PMID-sentid	Pub_year	Sent_text	comp_official_name	comp_offset	protein_name	organism	prot_offset
16730897-1	2006	The electrochemical oxidation of anionic surfactants (sodium dodecyl benzene sulfonate, DBS) contained in simulated wastewater treated by three-dimensional electrode system with combined modified kaolin served as packed bed particle electrodes and Ti/Co/SnO(2)-Sb(2)O(3) anode was studied, the chemical oxygen demand (COD) removal of pollutants in the solutions was also investigated.	dibromsalan	88-91	strawberry notch homolog 1	Homo sapiens	254-257
16751292-7	2006	SNO-hemoglobin dispenses NO bioactivity to microvascular cells on the release of oxygen, physiologically coupling hemoglobin deoxygenation to vasodilation.	Oxygen	81-87	strawberry notch homolog 1	Homo sapiens	0-3
16913744-1	2006	Single-crystalline SnO(2) nanocones with an average 1.0 mum in length and 100-500 nm in root size and their self-assembly morphologies were obtained through a solvothermal process in the presence of poly(acrylic acid).	poly	199-203	strawberry notch homolog 1	Homo sapiens	19-22
21727597-1	2006	SnO(2)/Sn nanocables have been grown on single-crystal Si substrates by metal catalyst assisted thermal evaporation of SnO powders.	Tin	0-2	strawberry notch homolog 1	Homo sapiens	119-122
21727597-1	2006	SnO(2)/Sn nanocables have been grown on single-crystal Si substrates by metal catalyst assisted thermal evaporation of SnO powders.	Silicon	55-57	strawberry notch homolog 1	Homo sapiens	0-3
21727597-1	2006	SnO(2)/Sn nanocables have been grown on single-crystal Si substrates by metal catalyst assisted thermal evaporation of SnO powders.	Metals	72-77	strawberry notch homolog 1	Homo sapiens	0-3
21727597-1	2006	SnO(2)/Sn nanocables have been grown on single-crystal Si substrates by metal catalyst assisted thermal evaporation of SnO powders.	Metals	72-77	strawberry notch homolog 1	Homo sapiens	119-122
21727533-1	2006	We investigate the effects of erbium doping on SnO(2) nanoclustering in Sn-doped silica.	Silicon Dioxide	81-87	strawberry notch homolog 1	Homo sapiens	47-50
16913744-1	2006	Single-crystalline SnO(2) nanocones with an average 1.0 mum in length and 100-500 nm in root size and their self-assembly morphologies were obtained through a solvothermal process in the presence of poly(acrylic acid).	acrylic acid	204-216	strawberry notch homolog 1	Homo sapiens	19-22
16339397-1	2006	The SNO-Hb hypothesis holds that heme-bound nitric oxide (NO) present in the beta subunits of T-state hemoglobin (Hb) will be transferred to the beta-93 cysteine upon conversion to R-state Hb, thereby forming SNO-Hb.	-93 cysteine	149-161	strawberry notch homolog 1	Homo sapiens	4-7
16813429-3	2006	In both cases, the SNO donor atoms of the tridentate ligand occupy the three positions in the equatorial plane of the distorted octahedron, whereas the oxo group is always directed toward one of the apical positions.	octahedron	128-138	strawberry notch homolog 1	Homo sapiens	19-22
16813429-5	2006	The [SNO][NN] mixed-ligand system was applied in the synthesis of the oxorhenium complex 5 in which the 1-(2-methoxyphenyl)piperazine moiety, a fragment of the true 5-HT1A antagonist WAY 100635, has been incorporated in the NN bidentate ligand (NN is N-{3-[4-(2-methoxyphenyl)piperazin-1-yl]propyl}pyridine-2-aldimine).	Nitrogen	10-12	strawberry notch homolog 1	Homo sapiens	5-8
16813429-5	2006	The [SNO][NN] mixed-ligand system was applied in the synthesis of the oxorhenium complex 5 in which the 1-(2-methoxyphenyl)piperazine moiety, a fragment of the true 5-HT1A antagonist WAY 100635, has been incorporated in the NN bidentate ligand (NN is N-{3-[4-(2-methoxyphenyl)piperazin-1-yl]propyl}pyridine-2-aldimine).	perrhenate	70-80	strawberry notch homolog 1	Homo sapiens	5-8
16813429-5	2006	The [SNO][NN] mixed-ligand system was applied in the synthesis of the oxorhenium complex 5 in which the 1-(2-methoxyphenyl)piperazine moiety, a fragment of the true 5-HT1A antagonist WAY 100635, has been incorporated in the NN bidentate ligand (NN is N-{3-[4-(2-methoxyphenyl)piperazin-1-yl]propyl}pyridine-2-aldimine).	1-(2-methoxyphenyl)piperazine	104-133	strawberry notch homolog 1	Homo sapiens	5-8
16813429-5	2006	The [SNO][NN] mixed-ligand system was applied in the synthesis of the oxorhenium complex 5 in which the 1-(2-methoxyphenyl)piperazine moiety, a fragment of the true 5-HT1A antagonist WAY 100635, has been incorporated in the NN bidentate ligand (NN is N-{3-[4-(2-methoxyphenyl)piperazin-1-yl]propyl}pyridine-2-aldimine).	nn bidentate	224-236	strawberry notch homolog 1	Homo sapiens	5-8
16813429-5	2006	The [SNO][NN] mixed-ligand system was applied in the synthesis of the oxorhenium complex 5 in which the 1-(2-methoxyphenyl)piperazine moiety, a fragment of the true 5-HT1A antagonist WAY 100635, has been incorporated in the NN bidentate ligand (NN is N-{3-[4-(2-methoxyphenyl)piperazin-1-yl]propyl}pyridine-2-aldimine).	Nitrogen	224-226	strawberry notch homolog 1	Homo sapiens	5-8
16813429-5	2006	The [SNO][NN] mixed-ligand system was applied in the synthesis of the oxorhenium complex 5 in which the 1-(2-methoxyphenyl)piperazine moiety, a fragment of the true 5-HT1A antagonist WAY 100635, has been incorporated in the NN bidentate ligand (NN is N-{3-[4-(2-methoxyphenyl)piperazin-1-yl]propyl}pyridine-2-aldimine).	n-{3-[4-(2-methoxyphenyl)piperazin-1-yl]propyl}pyridine-2-aldimine	251-317	strawberry notch homolog 1	Homo sapiens	5-8
16813429-1	2006	The present paper deals with the synthesis and structural characterization of novel neutral oxorhenium(V) complexes of the general formula ReO[SNO][NN].	perrhenate	92-102	strawberry notch homolog 1	Homo sapiens	143-146
16813429-1	2006	The present paper deals with the synthesis and structural characterization of novel neutral oxorhenium(V) complexes of the general formula ReO[SNO][NN].	Nitrogen	148-150	strawberry notch homolog 1	Homo sapiens	143-146
16710485-4	2006	The DFT calculated (13)C chemical shift for acetone adsorbed on MoO(3)/SnO(2) is in good agreement with the experimental value, which confirms our proposed structure of -Mo-(OH)-Sn- for the Bronsted acid site.	Acetone	44-51	strawberry notch homolog 1	Homo sapiens	71-74
16710485-4	2006	The DFT calculated (13)C chemical shift for acetone adsorbed on MoO(3)/SnO(2) is in good agreement with the experimental value, which confirms our proposed structure of -Mo-(OH)-Sn- for the Bronsted acid site.	bronsted acid	190-203	strawberry notch homolog 1	Homo sapiens	71-74
16339397-1	2006	The SNO-Hb hypothesis holds that heme-bound nitric oxide (NO) present in the beta subunits of T-state hemoglobin (Hb) will be transferred to the beta-93 cysteine upon conversion to R-state Hb, thereby forming SNO-Hb.	Heme	33-37	strawberry notch homolog 1	Homo sapiens	4-7
16339397-1	2006	The SNO-Hb hypothesis holds that heme-bound nitric oxide (NO) present in the beta subunits of T-state hemoglobin (Hb) will be transferred to the beta-93 cysteine upon conversion to R-state Hb, thereby forming SNO-Hb.	Heme	33-37	strawberry notch homolog 1	Homo sapiens	209-212
16339397-1	2006	The SNO-Hb hypothesis holds that heme-bound nitric oxide (NO) present in the beta subunits of T-state hemoglobin (Hb) will be transferred to the beta-93 cysteine upon conversion to R-state Hb, thereby forming SNO-Hb.	Nitric Oxide	44-56	strawberry notch homolog 1	Homo sapiens	4-7
16307886-1	2006	The adsorption of radioactive cobalt from aqueous solution on MgO, MnO(2), TiO(2), SnO, activated carbon and calcined hydrotalcite was studied under static conditions as a function of pH (1, 3, 5, 7, and 10) of the (60)Co solution.	Cobalt	30-36	strawberry notch homolog 1	Homo sapiens	83-86
16565424-5	2006	The circulating RBC is a major SNO reservoir, and RBC Hb releases SNO-related bioactivity peripherally on O2 desaturation.	Oxygen	106-108	strawberry notch homolog 1	Homo sapiens	66-69
16853611-6	2005	The specific capacity was found to be further improved when SnO(2) nanoparticles were supported on the carbon.	Carbon	103-109	strawberry notch homolog 1	Homo sapiens	60-63
16475808-8	2006	S-Nitrosylated Ras (Ras-SNO) can be formed when NO serves as a radical-quenching agent, and hydroxyl radical but not (*)NO(2) or O(2)(*)(-) can further react with Ras-SNO to modulate Ras activity in vitro.	Hydroxyl Radical	92-108	strawberry notch homolog 1	Homo sapiens	24-27
16475808-8	2006	S-Nitrosylated Ras (Ras-SNO) can be formed when NO serves as a radical-quenching agent, and hydroxyl radical but not (*)NO(2) or O(2)(*)(-) can further react with Ras-SNO to modulate Ras activity in vitro.	Hydroxyl Radical	92-108	strawberry notch homolog 1	Homo sapiens	167-170
16448092-0	2006	Thionitroxides, RSNHO*: the structure of the SNO moiety in "S-Nitrosohemoglobin", a possible NO reservoir and transporter.	thionitroxides	0-14	strawberry notch homolog 1	Homo sapiens	45-48
16448092-0	2006	Thionitroxides, RSNHO*: the structure of the SNO moiety in "S-Nitrosohemoglobin", a possible NO reservoir and transporter.	rsnho	16-21	strawberry notch homolog 1	Homo sapiens	45-48
16448092-5	2006	Computational studies show that the thionitroxide is the only structure consistent with the electron density in the hemoglobin Cysbeta93-SNO structure previously reported.	thionitroxide	36-49	strawberry notch homolog 1	Homo sapiens	137-140
15621271-4	2005	In (C(2)H(5))(2)Sn(Hmtc)Cl.THF, the ligand results monodeprotonated and, essentially, monodentate through the sulphur atom, while in (C(6)H(5))Sn(Hptc)Cl(2) the ligand is still monodeprotonated but SNO tridentate.	sn(hmtc)cl	16-26	strawberry notch homolog 1	Homo sapiens	198-201
15811508-3	2005	A common path to the formation of SNO-Hb involves oxidative transfer of the NO-group from heme to thiol.	Heme	90-94	strawberry notch homolog 1	Homo sapiens	34-37
15811508-3	2005	A common path to the formation of SNO-Hb involves oxidative transfer of the NO-group from heme to thiol.	Sulfhydryl Compounds	98-103	strawberry notch homolog 1	Homo sapiens	34-37
15811508-4	2005	We have previously reported that the reaction of nitrite with deoxy-Hb, which furnishes heme-Fe(II)NO, represents one attractive route for the formation of SNO-Hb.	Nitrites	49-56	strawberry notch homolog 1	Homo sapiens	156-159
15811508-4	2005	We have previously reported that the reaction of nitrite with deoxy-Hb, which furnishes heme-Fe(II)NO, represents one attractive route for the formation of SNO-Hb.	heme-fe(ii)no	88-101	strawberry notch homolog 1	Homo sapiens	156-159
15811508-8	2005	We further show in bioassay experiments that combinations of nitrite and deoxy-Hb--under conditions that suppress SNO-Hb formation--exhibit no direct vasodilatory activity.	Nitrites	61-68	strawberry notch homolog 1	Homo sapiens	114-117
16218730-1	2005	Programmable control over the overall structure of SnO(2) nanowires grown by vapor-solid synthesis is shown to be possible by pulse modulating the flow rate of the carrier gas in which oxygen (one of the reactants) is entrained.	Oxygen	185-191	strawberry notch homolog 1	Homo sapiens	51-54
15797251-1	2005	The mechanisms of formation of S-nitrosothiols under physiological conditions and, in particular, of generation of SNO-Hb (the hemoglobin form in which the cysteine residues beta93 are S-nitrosated) are still not completely understood.	Cysteine	156-164	strawberry notch homolog 1	Homo sapiens	115-118
15797251-4	2005	Since the environment of the cysteine residue beta93 is rather hydrophobic, these conditions facilitate SNO-Hb production.	Cysteine	29-37	strawberry notch homolog 1	Homo sapiens	104-107
15699345-3	2005	Here we show that sickle cell Hb variant S (HbS) is deficient both in the intramolecular transfer of NO from heme iron (iron nitrosyl, FeNO) to cysteine thiol (S-nitrosothiol, SNO) that subserves bioactivation, and in transfer of the NO moiety from S-nitrosohemoglobin (SNO-HbS) to the RBC membrane.	Heme	109-113	strawberry notch homolog 1	Homo sapiens	176-179
15699345-3	2005	Here we show that sickle cell Hb variant S (HbS) is deficient both in the intramolecular transfer of NO from heme iron (iron nitrosyl, FeNO) to cysteine thiol (S-nitrosothiol, SNO) that subserves bioactivation, and in transfer of the NO moiety from S-nitrosohemoglobin (SNO-HbS) to the RBC membrane.	Heme	109-113	strawberry notch homolog 1	Homo sapiens	270-273
15621271-4	2005	In (C(2)H(5))(2)Sn(Hmtc)Cl.THF, the ligand results monodeprotonated and, essentially, monodentate through the sulphur atom, while in (C(6)H(5))Sn(Hptc)Cl(2) the ligand is still monodeprotonated but SNO tridentate.	tetrahydrofuran	27-30	strawberry notch homolog 1	Homo sapiens	198-201
15621271-4	2005	In (C(2)H(5))(2)Sn(Hmtc)Cl.THF, the ligand results monodeprotonated and, essentially, monodentate through the sulphur atom, while in (C(6)H(5))Sn(Hptc)Cl(2) the ligand is still monodeprotonated but SNO tridentate.	(c(6)h(5))sn(hptc)cl	133-153	strawberry notch homolog 1	Homo sapiens	198-201
15698092-4	2005	By creating a relatively uniform density plasma with a 300 microm diameter by dispersing SnO(2) particles coated on a Si wafer, the conversion efficiency at 14 nm, as high as 4 times as that for a Sn plate target, is achieved.	Silicon	118-120	strawberry notch homolog 1	Homo sapiens	89-92
15519294-6	2004	We examine with this system the transnitrosylation reaction between CysNO and BSA at low molecular ratios and could assay nitrites, SNO-BSA, and CysNO in the incubation mixture without any preliminary purification steps.	S-nitrosocysteine	68-73	strawberry notch homolog 1	Homo sapiens	132-135
15569857-1	2005	S-nitrosoalbumin (SNO-Alb) is a major reservoir of releasable nitric oxide (NO) in plasma.	Nitric Oxide	62-74	strawberry notch homolog 1	Homo sapiens	18-21
15569857-3	2005	This increased SNO-Alb may result from low-plasma Asc if Asc, along with transition metals (eg, copper [Cu]) are necessary for release of NO from S-nitrosothiols.	Copper	96-102	strawberry notch homolog 1	Homo sapiens	15-18
15569857-3	2005	This increased SNO-Alb may result from low-plasma Asc if Asc, along with transition metals (eg, copper [Cu]) are necessary for release of NO from S-nitrosothiols.	Copper	104-106	strawberry notch homolog 1	Homo sapiens	15-18
15569857-3	2005	This increased SNO-Alb may result from low-plasma Asc if Asc, along with transition metals (eg, copper [Cu]) are necessary for release of NO from S-nitrosothiols.	S-Nitrosothiols	146-161	strawberry notch homolog 1	Homo sapiens	15-18
15569857-4	2005	We propose that vasodilator effects of SNO-Alb, mediated by release of NO, are fully realized only when Asc/Cu availability is sufficient.	Ascorbic Acid	104-107	strawberry notch homolog 1	Homo sapiens	39-42
15569857-4	2005	We propose that vasodilator effects of SNO-Alb, mediated by release of NO, are fully realized only when Asc/Cu availability is sufficient.	Copper	108-110	strawberry notch homolog 1	Homo sapiens	39-42
15569857-12	2005	We suggest that the higher circulating levels of SNO-Alb, in women with preeclampsia, reflect a deficiency in Asc/Cu-mediated release of NO from SNO-Alb.	Ascorbic Acid	110-113	strawberry notch homolog 1	Homo sapiens	49-52
15569857-12	2005	We suggest that the higher circulating levels of SNO-Alb, in women with preeclampsia, reflect a deficiency in Asc/Cu-mediated release of NO from SNO-Alb.	Ascorbic Acid	110-113	strawberry notch homolog 1	Homo sapiens	145-148
15569857-12	2005	We suggest that the higher circulating levels of SNO-Alb, in women with preeclampsia, reflect a deficiency in Asc/Cu-mediated release of NO from SNO-Alb.	Copper	114-116	strawberry notch homolog 1	Homo sapiens	49-52
15569857-12	2005	We suggest that the higher circulating levels of SNO-Alb, in women with preeclampsia, reflect a deficiency in Asc/Cu-mediated release of NO from SNO-Alb.	Copper	114-116	strawberry notch homolog 1	Homo sapiens	145-148
16291225-2	2005	As a general rule, SNO formation requires the presence of an electron acceptor such as Cu2+.	cupric ion	87-91	strawberry notch homolog 1	Homo sapiens	19-22
18969637-0	2004	Qualitative and quantitative analysis of organophosphorus pesticide residues using temperature modulated SnO(2) gas sensor.	organophosphorus	41-57	strawberry notch homolog 1	Homo sapiens	105-108
15491223-6	2004	Ni-P electroless plating was carried out on the photopatterned adsorption films, using three types of SnO(x) colloidal materials without and with cationic or anionic surfactant as catalyst precursors in the sensitization step.	ni-p	0-4	strawberry notch homolog 1	Homo sapiens	102-105
15491223-9	2004	It was obvious by ICP-AES analyses that the hydrophobic long-chain dodecyl groups in the adsorption film could promote the adsorption of the negative SnO(x) colloids on the film surface, followed by much nucleus formation of zerovalent Pd catalysts useful for the electroless plating.	Palladium	236-238	strawberry notch homolog 1	Homo sapiens	150-153
15491223-10	2004	The result of our experiment clearly showed that, in addition to electrostatic interaction, van der Waals interaction generating between the hydrophobic long-chain hydrocarbons of the adsorption film and the surfactant improved significantly the adsorption stability of the SnO(x) colloids, resulting in highly selective Ni-deposition in accord with the photopattern shape of the cationic single-layer adsorption film.	Hydrocarbons	164-176	strawberry notch homolog 1	Homo sapiens	274-277
15452643-0	2004	Structural and electrical characterisation of Li(2)O : TiO(2) : SnO(2) : P(2)O(5) electrolyte glass.	li(2)o	46-52	strawberry notch homolog 1	Homo sapiens	64-67
15452643-0	2004	Structural and electrical characterisation of Li(2)O : TiO(2) : SnO(2) : P(2)O(5) electrolyte glass.	titanium dioxide	55-61	strawberry notch homolog 1	Homo sapiens	64-67
15267790-2	2004	We study the spectroscopic parameters and electron affinity of the tin oxide molecule SnO and its anion SnO(-) applying nonrelativistic as well as relativistic calculations with higher orders of the DK approximation.	stannic oxide	67-76	strawberry notch homolog 1	Homo sapiens	86-89
15144832-0	2004	Copper (II) adsorbed on SiO(2)/SnO(2) obtained by the sol-gel processing method: application as electrochemical sensor for ascorbic acid.	cupric ion	0-11	strawberry notch homolog 1	Homo sapiens	31-34
15144832-2	2004	The procedure for SiO(2)/SnO(2) mixed oxide preparation using the sol-gel processing method, starting from tetraethylorthosilicate and SnI(4) as precursor reagents, is described.	tetraethoxysilane	107-130	strawberry notch homolog 1	Homo sapiens	25-28
15144832-2	2004	The procedure for SiO(2)/SnO(2) mixed oxide preparation using the sol-gel processing method, starting from tetraethylorthosilicate and SnI(4) as precursor reagents, is described.	sni(4)	135-141	strawberry notch homolog 1	Homo sapiens	25-28
15258951-0	2004	Molecular [(SnO)6] trapped by two [R2Si2O3] fragments: X-ray single-crystal structure of [(SnO)6(R2Si2O3)2].	[r2si2o3	34-42	strawberry notch homolog 1	Homo sapiens	12-15
15258951-0	2004	Molecular [(SnO)6] trapped by two [R2Si2O3] fragments: X-ray single-crystal structure of [(SnO)6(R2Si2O3)2].	[r2si2o3	34-42	strawberry notch homolog 1	Homo sapiens	91-94
11796706-3	2002	Here we utilize antibodies specific for the nitrosothiol (SNO) moiety to provide an immunohistochemical demonstration that protein S-nitrosylation is coupled to the activity of each of the major forms of NOS.	S-Nitrosothiols	44-56	strawberry notch homolog 1	Homo sapiens	58-61
15775054-4	2004	It is found that the most stable complexes are formed when Cu(+) coordinates to the S-nitrosothiol via S of the SNO group.	Copper	59-64	strawberry notch homolog 1	Homo sapiens	112-115
15775054-4	2004	It is found that the most stable complexes are formed when Cu(+) coordinates to the S-nitrosothiol via S of the SNO group.	S-Nitrosothiols	84-98	strawberry notch homolog 1	Homo sapiens	112-115
15775054-6	2004	In contrast, when Cu(+) coordinates via the nitrogen of the SNO group, a shortening of the SN bond with lengthening of the NO bond is observed.	Copper	18-23	strawberry notch homolog 1	Homo sapiens	60-63
15775054-6	2004	In contrast, when Cu(+) coordinates via the nitrogen of the SNO group, a shortening of the SN bond with lengthening of the NO bond is observed.	Nitrogen	44-52	strawberry notch homolog 1	Homo sapiens	60-63
12639140-5	2003	In 3 and 4, a similar pentacoordination is present; the copper atom is surrounded by the ligand SNO donor atoms and by two chloride ions.	Copper	56-62	strawberry notch homolog 1	Homo sapiens	96-99
12639140-7	2003	The copper coordination (4 + 2) involves the SNO ligand atoms and a water oxygen in the basal plane; the apical positions are occupied by a second water oxygen and by an oxygen of a monodentate nitrate group.	Copper	4-10	strawberry notch homolog 1	Homo sapiens	45-48
12296738-7	2002	The KOH-catalyzed reaction of other metal oxides was explored including B(2)O(3), Ga(2)O(3), TiO(2), Sb(2)O(3), SnO(2), and SnO.	potassium hydroxide	4-7	strawberry notch homolog 1	Homo sapiens	112-115
12296738-7	2002	The KOH-catalyzed reaction of other metal oxides was explored including B(2)O(3), Ga(2)O(3), TiO(2), Sb(2)O(3), SnO(2), and SnO.	potassium hydroxide	4-7	strawberry notch homolog 1	Homo sapiens	124-127
12042776-2	2002	Here we show that in in vitro and ex vivo systems as well as healthy adults alternately exposed to hypoxia or hyperoxia (to dilate or constrict pulmonary and systemic arteries in vivo), binding of NO to hemes (FeNO) and thiols (SNO) of Hb varies as a function of HbO(2) saturation (FeO(2)).	Heme	203-208	strawberry notch homolog 1	Homo sapiens	228-231
11929246-2	2002	Typically, the reaction of alpha-heterosubstituted alcohols with 1 equiv of p-TsCl and 1 equiv of Et(3)N in the presence of 2 mol % of Bu(2)SnO leads to rapid, regioselective, and exclusive monotosylation.	Alcohols	51-59	strawberry notch homolog 1	Homo sapiens	140-143
11929246-2	2002	Typically, the reaction of alpha-heterosubstituted alcohols with 1 equiv of p-TsCl and 1 equiv of Et(3)N in the presence of 2 mol % of Bu(2)SnO leads to rapid, regioselective, and exclusive monotosylation.	4-toluenesulfonyl chloride	76-82	strawberry notch homolog 1	Homo sapiens	140-143
11929246-2	2002	Typically, the reaction of alpha-heterosubstituted alcohols with 1 equiv of p-TsCl and 1 equiv of Et(3)N in the presence of 2 mol % of Bu(2)SnO leads to rapid, regioselective, and exclusive monotosylation.	et(3)n	98-104	strawberry notch homolog 1	Homo sapiens	140-143
11929246-2	2002	Typically, the reaction of alpha-heterosubstituted alcohols with 1 equiv of p-TsCl and 1 equiv of Et(3)N in the presence of 2 mol % of Bu(2)SnO leads to rapid, regioselective, and exclusive monotosylation.	Busulfan	135-137	strawberry notch homolog 1	Homo sapiens	140-143
12724752-0	2003	Nitric oxide"s reactions with hemoglobin: a view through the SNO-storm.	Nitric Oxide	0-12	strawberry notch homolog 1	Homo sapiens	61-64
12590530-1	2003	BN nanotubes are coated with SnO(2) by a simple chemical reaction in solution.	6-bromo-2-naphthyl sulfate	0-2	strawberry notch homolog 1	Homo sapiens	29-32
12296738-10	2002	SnO reacted with DMC to give a mixture that included (MeO)(4)Sn and possibly Me(3)Sn(OMe).	methyl carbonate	17-20	strawberry notch homolog 1	Homo sapiens	0-3
12121110-6	2002	The result shows that the phase transformation from SnO to SnO(2) occurs in two processes of decomposition and oxidization, and the decomposition process consists of two steps: first from SnO to Sn(3)O(4) and then from Sn(3)O(4) to SnO(2).	Tin	52-54	strawberry notch homolog 1	Homo sapiens	59-62
12121110-6	2002	The result shows that the phase transformation from SnO to SnO(2) occurs in two processes of decomposition and oxidization, and the decomposition process consists of two steps: first from SnO to Sn(3)O(4) and then from Sn(3)O(4) to SnO(2).	Tin	52-54	strawberry notch homolog 1	Homo sapiens	59-62
12121110-6	2002	The result shows that the phase transformation from SnO to SnO(2) occurs in two processes of decomposition and oxidization, and the decomposition process consists of two steps: first from SnO to Sn(3)O(4) and then from Sn(3)O(4) to SnO(2).	Tin	52-54	strawberry notch homolog 1	Homo sapiens	59-62
12121110-6	2002	The result shows that the phase transformation from SnO to SnO(2) occurs in two processes of decomposition and oxidization, and the decomposition process consists of two steps: first from SnO to Sn(3)O(4) and then from Sn(3)O(4) to SnO(2).	Tin	59-61	strawberry notch homolog 1	Homo sapiens	52-55
10219141-7	1998	The alloy surfaces were analyzed by XPS and showed that oxides such as In2O3, ZnO, or SnO play an important role in improving the adhesive ability of the alloys.	Oxides	56-62	strawberry notch homolog 1	Homo sapiens	86-89
11421676-3	2001	The structure of AV-10 is composed of corner sharing SnO(6) octahedra and SiO(4) tetrahedra, forming a three-dimensional framework structure.	Eprociclovir	17-22	strawberry notch homolog 1	Homo sapiens	53-56
11421676-4	2001	The SiO(4) tetrahedra form helix chains along [001] interconnected by SnO(6) octahedra.	sio(4) tetrahedra	4-21	strawberry notch homolog 1	Homo sapiens	70-73
11421676-5	2001	The SnO(6) octahedra are isolated by SiO(4) tetrahedra and, thus, there are no Sn-O-Sn linkages.	sio(4) tetrahedra	37-54	strawberry notch homolog 1	Homo sapiens	4-7
11401386-3	2001	Observation on dye-sensitizated photoelectrochemical cells made from SnO(2)/ZnO films sensitized with different dyes suggests that the electron transfer could occur in either direction, that is from semiconductor of high band position to the semiconductor of the low band position or vice versa, depending on which surface adsorbs the dye more strongly.	Zinc Oxide	76-79	strawberry notch homolog 1	Homo sapiens	69-72
11139362-7	2000	In this paper, we describe a new method for the quantitative assay of SNO-Hb, after the liberation of NO by Cu(2+)/Cu(+) and the simultaneous assessment of NO by solid-state amperometric sensor.	cupric ion	108-114	strawberry notch homolog 1	Homo sapiens	70-73
11139362-7	2000	In this paper, we describe a new method for the quantitative assay of SNO-Hb, after the liberation of NO by Cu(2+)/Cu(+) and the simultaneous assessment of NO by solid-state amperometric sensor.	Copper	108-110	strawberry notch homolog 1	Homo sapiens	70-73
11139362-9	2000	For this reason, we believe that it may represent an important analytical improvement for the study of the S-transnitrosylation reactions between RSNO and the Hb Cys-beta 93 and SNO-Hb and glutathione.	Cysteine	162-165	strawberry notch homolog 1	Homo sapiens	147-150
11139362-9	2000	For this reason, we believe that it may represent an important analytical improvement for the study of the S-transnitrosylation reactions between RSNO and the Hb Cys-beta 93 and SNO-Hb and glutathione.	Glutathione	189-200	strawberry notch homolog 1	Homo sapiens	147-150
18066151-0	2000	Bragg gratings in ternary SiO(2):SnO(2):Na(2)O optical glass fibers.	sodium sulfide	40-45	strawberry notch homolog 1	Homo sapiens	33-36
18066151-2	2000	The presence of Na(2)O allows for higher concentrations of SnO>(2) , which are believed to be responsible for the photorefractive response of this composition.	sodium oxide	16-22	strawberry notch homolog 1	Homo sapiens	59-62
9473434-0	1998	The VUV Absorption Spectrum of the Tin Monoxide Molecule The absorption spectrum of heated SnO between 2000 and 300 A has been recorded using the facilities of the SuperACO synchrotron at Orsay, France.	Tin(II) oxide	35-47	strawberry notch homolog 1	Homo sapiens	91-94
18301567-6	1998	Varying the oxygen partial pressure during deposition made it possible to obtain films whose complex refractive index changed at the transition from SnO to SnO(2).	Oxygen	12-18	strawberry notch homolog 1	Homo sapiens	149-152
18301567-6	1998	Varying the oxygen partial pressure during deposition made it possible to obtain films whose complex refractive index changed at the transition from SnO to SnO(2).	Oxygen	12-18	strawberry notch homolog 1	Homo sapiens	156-159
11670654-0	1998	Reactions of [t-Bu(2)SnO](3) with [t-BuX(2)Si](2) (X = F, Cl).	t-bux(2)si	35-45	strawberry notch homolog 1	Homo sapiens	21-24
11670654-0	1998	Reactions of [t-Bu(2)SnO](3) with [t-BuX(2)Si](2) (X = F, Cl).	Fluorine	55-56	strawberry notch homolog 1	Homo sapiens	21-24
11670654-2	1998	Di-tert-butyltin oxide, (t-Bu(2)SnO)(3) (1), reacts with 1,2-di-tert-butyltetrachlorodisilane, (t-BuCl(2)Si)(2) (2), to provide the stannasiloxane t-Bu(2)Sn[OSi(OSnCl-t-Bu(2))-t-Bu](2) (4, racemate).	di-tert-butyltin oxide	0-22	strawberry notch homolog 1	Homo sapiens	32-35
11670654-2	1998	Di-tert-butyltin oxide, (t-Bu(2)SnO)(3) (1), reacts with 1,2-di-tert-butyltetrachlorodisilane, (t-BuCl(2)Si)(2) (2), to provide the stannasiloxane t-Bu(2)Sn[OSi(OSnCl-t-Bu(2))-t-Bu](2) (4, racemate).	1,2-di-tert-butyltetrachlorodisilane	57-93	strawberry notch homolog 1	Homo sapiens	32-35
11670654-2	1998	Di-tert-butyltin oxide, (t-Bu(2)SnO)(3) (1), reacts with 1,2-di-tert-butyltetrachlorodisilane, (t-BuCl(2)Si)(2) (2), to provide the stannasiloxane t-Bu(2)Sn[OSi(OSnCl-t-Bu(2))-t-Bu](2) (4, racemate).	2-Chloro-2-methylpropane	96-102	strawberry notch homolog 1	Homo sapiens	32-35
11670654-2	1998	Di-tert-butyltin oxide, (t-Bu(2)SnO)(3) (1), reacts with 1,2-di-tert-butyltetrachlorodisilane, (t-BuCl(2)Si)(2) (2), to provide the stannasiloxane t-Bu(2)Sn[OSi(OSnCl-t-Bu(2))-t-Bu](2) (4, racemate).	stannasiloxane t-bu	132-151	strawberry notch homolog 1	Homo sapiens	32-35
11670654-2	1998	Di-tert-butyltin oxide, (t-Bu(2)SnO)(3) (1), reacts with 1,2-di-tert-butyltetrachlorodisilane, (t-BuCl(2)Si)(2) (2), to provide the stannasiloxane t-Bu(2)Sn[OSi(OSnCl-t-Bu(2))-t-Bu](2) (4, racemate).	sn[osi(osncl-t-bu	154-171	strawberry notch homolog 1	Homo sapiens	32-35
11670654-2	1998	Di-tert-butyltin oxide, (t-Bu(2)SnO)(3) (1), reacts with 1,2-di-tert-butyltetrachlorodisilane, (t-BuCl(2)Si)(2) (2), to provide the stannasiloxane t-Bu(2)Sn[OSi(OSnCl-t-Bu(2))-t-Bu](2) (4, racemate).	)-t-bu	174-180	strawberry notch homolog 1	Homo sapiens	32-35
18967059-1	1998	Mesoporous SnO(2) with high surface areas were synthesized using a cationic surfactant (N-cetyl-N,N,N-trimethylammonium bromide) as a synthetic template.	Cetrimonium	88-127	strawberry notch homolog 1	Homo sapiens	11-14
18967059-6	1998	It was observed that SnO(2) with higher surface areas had much higher sensitivities to hydrogen at 573 K.	Hydrogen	87-95	strawberry notch homolog 1	Homo sapiens	21-24
11669818-5	1997	NMR data indicate that reaction between ((t)Bu(2)SnO)(3) and (t)Bu(2)SnCl(2) gives rise to an equilibrium involving linear [(t)Bu(2)Sn(Cl)OSn(Cl)(t)Bu(2)] and the novel three-quarter ladder compound [(t)Bu(2)SnCl(2)][(t)Bu(2)SnO](2).	sn(cl)osn	132-141	strawberry notch homolog 1	Homo sapiens	49-52
11670190-1	1997	The reaction of [(Me(2)Sn)(2)(Me(2)SnO)(ONZOH)(HONZO)(ONZO)] (HONZOH = o-HON=CHC(6)H(4)OH, salicylaldoxime) with ammonium fluoride yields a fluorotris(dimethyltin) disalicylaldoximate complex, compound 4, containing one seven-coordinate and two five-coordinate tin atoms, with a fluoride anion bridging the five-coordinate tin atoms.	me(2)sn	18-25	strawberry notch homolog 1	Homo sapiens	35-38
11670190-1	1997	The reaction of [(Me(2)Sn)(2)(Me(2)SnO)(ONZOH)(HONZO)(ONZO)] (HONZOH = o-HON=CHC(6)H(4)OH, salicylaldoxime) with ammonium fluoride yields a fluorotris(dimethyltin) disalicylaldoximate complex, compound 4, containing one seven-coordinate and two five-coordinate tin atoms, with a fluoride anion bridging the five-coordinate tin atoms.	chc(6)h(4)oh	77-89	strawberry notch homolog 1	Homo sapiens	35-38
18475857-0	1998	Studies on Some Biologically Cobalt(II), Copper(II) and Zinc(II) Complexes With ONO, NNO and SNO Donor Pyrazinoylhydrazine-Derived Ligands.	Cobalt(2+)	29-39	strawberry notch homolog 1	Homo sapiens	93-96
18475857-0	1998	Studies on Some Biologically Cobalt(II), Copper(II) and Zinc(II) Complexes With ONO, NNO and SNO Donor Pyrazinoylhydrazine-Derived Ligands.	cupric ion	41-51	strawberry notch homolog 1	Homo sapiens	93-96
18475857-0	1998	Studies on Some Biologically Cobalt(II), Copper(II) and Zinc(II) Complexes With ONO, NNO and SNO Donor Pyrazinoylhydrazine-Derived Ligands.	Zinc	56-64	strawberry notch homolog 1	Homo sapiens	93-96
18475857-0	1998	Studies on Some Biologically Cobalt(II), Copper(II) and Zinc(II) Complexes With ONO, NNO and SNO Donor Pyrazinoylhydrazine-Derived Ligands.	pyrazinoylhydrazine	103-122	strawberry notch homolog 1	Homo sapiens	93-96
18475857-1	1998	Biologically active complexes of Co(II), Ni(II), Cu(II) and Zn(II) with novel ONO, NNO and SNO donor pyrazinoylhydrazine-derived compounds have been prepared and characterized on the basis of analytical data and various physicochemical studies.	Cobalt(2+)	33-39	strawberry notch homolog 1	Homo sapiens	91-94
18475857-1	1998	Biologically active complexes of Co(II), Ni(II), Cu(II) and Zn(II) with novel ONO, NNO and SNO donor pyrazinoylhydrazine-derived compounds have been prepared and characterized on the basis of analytical data and various physicochemical studies.	Nickel(2+)	41-47	strawberry notch homolog 1	Homo sapiens	91-94
18475857-1	1998	Biologically active complexes of Co(II), Ni(II), Cu(II) and Zn(II) with novel ONO, NNO and SNO donor pyrazinoylhydrazine-derived compounds have been prepared and characterized on the basis of analytical data and various physicochemical studies.	cu(ii)	49-55	strawberry notch homolog 1	Homo sapiens	91-94
18475857-1	1998	Biologically active complexes of Co(II), Ni(II), Cu(II) and Zn(II) with novel ONO, NNO and SNO donor pyrazinoylhydrazine-derived compounds have been prepared and characterized on the basis of analytical data and various physicochemical studies.	Zinc	60-66	strawberry notch homolog 1	Homo sapiens	91-94
18475857-1	1998	Biologically active complexes of Co(II), Ni(II), Cu(II) and Zn(II) with novel ONO, NNO and SNO donor pyrazinoylhydrazine-derived compounds have been prepared and characterized on the basis of analytical data and various physicochemical studies.	pyrazinoylhydrazine	101-120	strawberry notch homolog 1	Homo sapiens	91-94
11669818-5	1997	NMR data indicate that reaction between ((t)Bu(2)SnO)(3) and (t)Bu(2)SnCl(2) gives rise to an equilibrium involving linear [(t)Bu(2)Sn(Cl)OSn(Cl)(t)Bu(2)] and the novel three-quarter ladder compound [(t)Bu(2)SnCl(2)][(t)Bu(2)SnO](2).	sn(cl)osn	132-141	strawberry notch homolog 1	Homo sapiens	225-228
11669818-5	1997	NMR data indicate that reaction between ((t)Bu(2)SnO)(3) and (t)Bu(2)SnCl(2) gives rise to an equilibrium involving linear [(t)Bu(2)Sn(Cl)OSn(Cl)(t)Bu(2)] and the novel three-quarter ladder compound [(t)Bu(2)SnCl(2)][(t)Bu(2)SnO](2).	2)sncl	67-73	strawberry notch homolog 1	Homo sapiens	49-52
11669818-5	1997	NMR data indicate that reaction between ((t)Bu(2)SnO)(3) and (t)Bu(2)SnCl(2) gives rise to an equilibrium involving linear [(t)Bu(2)Sn(Cl)OSn(Cl)(t)Bu(2)] and the novel three-quarter ladder compound [(t)Bu(2)SnCl(2)][(t)Bu(2)SnO](2).	2)sncl	67-73	strawberry notch homolog 1	Homo sapiens	225-228
8674114-5	1996	The conclusion that sno-RNAs function in covalent modification of the sugar moieties of ribonucleotides demonstrates that eukaryotic small nuclear RNAs have a more versatile cellular function than earlier anticipated.	Sugars	70-75	strawberry notch homolog 1	Homo sapiens	20-23
8912514-7	1996	Both SNO-GSH and endogenous NO induced by cytokines inhibited this migration.	Glutathione	9-12	strawberry notch homolog 1	Homo sapiens	5-8
8912514-9	1996	These effects of SNO-GSH and cytokine-induced NO production were reversed in the presence of hemoglobin and the NO synthase inhibitor NG-monomethyl arginine, respectively.	ng-monomethyl arginine	134-156	strawberry notch homolog 1	Homo sapiens	17-20
33033273-1	2020	Tin monoxide (SnO) has attracted attention due to its p-type character and capability of ambipolar conductivity when properly doped, properties that are beneficial for the realization of complementary oxide thin film transistors technology, transparent flexible circuits and optoelectronic applications in general.	Tin(II) oxide	0-12	strawberry notch homolog 1	Homo sapiens	14-17
10018253-0	1994	Implication of gallium results on the possibility of observing day-night matter oscillations at SNO, Super-Kamiokande, and Borexino.	Gallium	15-22	strawberry notch homolog 1	Homo sapiens	96-99
9996724-0	1991	Crystallization study and hyperfine characterization of a Sn-O thin film with 181Ta.	181ta	78-83	strawberry notch homolog 1	Homo sapiens	58-62
33033273-1	2020	Tin monoxide (SnO) has attracted attention due to its p-type character and capability of ambipolar conductivity when properly doped, properties that are beneficial for the realization of complementary oxide thin film transistors technology, transparent flexible circuits and optoelectronic applications in general.	Oxides	7-12	strawberry notch homolog 1	Homo sapiens	14-17
33033273-4	2020	Alloying with Pb by element substitution increases the band gap of SnO without inducing defect states in the band gap retaining the anti-bonding character of the valence band maximum which is beneficial for p-type conductivity.	Lead	14-16	strawberry notch homolog 1	Homo sapiens	67-70
33033273-6	2020	A broken gap band alignment for the SnO/PbO heterojunction is calculated, which can be attractive for energy conversion in solar cells, photocatalysis and hydrogen generation.	Hydrogen	155-163	strawberry notch homolog 1	Homo sapiens	36-39
34788502-4	2022	For this, a well-designed synthetic route combining wet impregnation with a two-step thermal treatment process was established to construct PtSn/SnO x interfaces on carbon nanotubes.	ptsn	140-144	strawberry notch homolog 1	Homo sapiens	145-148
34653855-0	2022	Orange peel extract influenced partial transformation of SnO2 to SnO in green 3D-ZnO/SnO2 system for chlorophenol degradation.	Tin(IV) oxide	57-61	strawberry notch homolog 1	Homo sapiens	65-68
34653855-0	2022	Orange peel extract influenced partial transformation of SnO2 to SnO in green 3D-ZnO/SnO2 system for chlorophenol degradation.	Zinc Oxide	81-84	strawberry notch homolog 1	Homo sapiens	65-68
34653855-0	2022	Orange peel extract influenced partial transformation of SnO2 to SnO in green 3D-ZnO/SnO2 system for chlorophenol degradation.	Tin(IV) oxide	85-89	strawberry notch homolog 1	Homo sapiens	65-68
34653855-0	2022	Orange peel extract influenced partial transformation of SnO2 to SnO in green 3D-ZnO/SnO2 system for chlorophenol degradation.	Chlorophenols	101-113	strawberry notch homolog 1	Homo sapiens	65-68
34653855-7	2022	Elemental analysis showed that the partial amount of SnO2 has transformed to SnO due to the reducing ability of orange peel extract.	Tin(IV) oxide	53-57	strawberry notch homolog 1	Homo sapiens	77-80
33815647-3	2020	Results obtained by flowing hydrocarbons (CH4 and CH3CHCH2) unequivocally show that these gases react with surface hydroxyl groups to produce water without producing carbon oxides and release electrons that localize on Sn to eventually form SnO.	Hydrocarbons	28-40	strawberry notch homolog 1	Homo sapiens	241-244
33815647-3	2020	Results obtained by flowing hydrocarbons (CH4 and CH3CHCH2) unequivocally show that these gases react with surface hydroxyl groups to produce water without producing carbon oxides and release electrons that localize on Sn to eventually form SnO.	ch3chch2	50-58	strawberry notch homolog 1	Homo sapiens	241-244
33815647-3	2020	Results obtained by flowing hydrocarbons (CH4 and CH3CHCH2) unequivocally show that these gases react with surface hydroxyl groups to produce water without producing carbon oxides and release electrons that localize on Sn to eventually form SnO.	Hydroxyl Radical	115-123	strawberry notch homolog 1	Homo sapiens	241-244
33815647-3	2020	Results obtained by flowing hydrocarbons (CH4 and CH3CHCH2) unequivocally show that these gases react with surface hydroxyl groups to produce water without producing carbon oxides and release electrons that localize on Sn to eventually form SnO.	Water	142-147	strawberry notch homolog 1	Homo sapiens	241-244
34788502-4	2022	For this, a well-designed synthetic route combining wet impregnation with a two-step thermal treatment process was established to construct PtSn/SnO x interfaces on carbon nanotubes.	Carbon	165-171	strawberry notch homolog 1	Homo sapiens	145-148
34788502-5	2022	Using this route, the alloying of Pt-Sn and formation of PtSn-SnO x interfaces can simultaneously be achieved, and the coverage of SnO x thin films on PtSn alloy nanoparticles can be facilely tuned by the strong interaction between Pt and SnO x .	Platinum	34-36	strawberry notch homolog 1	Homo sapiens	239-242
34487927-1	2022	The nitrogen-doped carbon (NC) coating encapsulating heterostructural Sn/SnO2 microcube powders (Sn/SnO2@NC) are successfully fabricated through hydrothermal, polymerization of hydrogel, and carbonization processes, in which the SnO precursor powders exhibit regular microcube structure and uniform size distribution in the presence of optimized N2H4 H2O (3.0 mL of 1.0 mol/L).	Nitrogen	4-12	strawberry notch homolog 1	Homo sapiens	100-103
34788502-5	2022	Using this route, the alloying of Pt-Sn and formation of PtSn-SnO x interfaces can simultaneously be achieved, and the coverage of SnO x thin films on PtSn alloy nanoparticles can be facilely tuned by the strong interaction between Pt and SnO x .	Tin	37-39	strawberry notch homolog 1	Homo sapiens	239-242
34487927-1	2022	The nitrogen-doped carbon (NC) coating encapsulating heterostructural Sn/SnO2 microcube powders (Sn/SnO2@NC) are successfully fabricated through hydrothermal, polymerization of hydrogel, and carbonization processes, in which the SnO precursor powders exhibit regular microcube structure and uniform size distribution in the presence of optimized N2H4 H2O (3.0 mL of 1.0 mol/L).	Nitrogen	4-12	strawberry notch homolog 1	Homo sapiens	229-232
34788502-5	2022	Using this route, the alloying of Pt-Sn and formation of PtSn-SnO x interfaces can simultaneously be achieved, and the coverage of SnO x thin films on PtSn alloy nanoparticles can be facilely tuned by the strong interaction between Pt and SnO x .	ptsn	57-61	strawberry notch homolog 1	Homo sapiens	62-65
34487927-1	2022	The nitrogen-doped carbon (NC) coating encapsulating heterostructural Sn/SnO2 microcube powders (Sn/SnO2@NC) are successfully fabricated through hydrothermal, polymerization of hydrogel, and carbonization processes, in which the SnO precursor powders exhibit regular microcube structure and uniform size distribution in the presence of optimized N2H4 H2O (3.0 mL of 1.0 mol/L).	Carbon	19-25	strawberry notch homolog 1	Homo sapiens	100-103
34487927-1	2022	The nitrogen-doped carbon (NC) coating encapsulating heterostructural Sn/SnO2 microcube powders (Sn/SnO2@NC) are successfully fabricated through hydrothermal, polymerization of hydrogel, and carbonization processes, in which the SnO precursor powders exhibit regular microcube structure and uniform size distribution in the presence of optimized N2H4 H2O (3.0 mL of 1.0 mol/L).	Carbon	19-25	strawberry notch homolog 1	Homo sapiens	229-232
34788502-5	2022	Using this route, the alloying of Pt-Sn and formation of PtSn-SnO x interfaces can simultaneously be achieved, and the coverage of SnO x thin films on PtSn alloy nanoparticles can be facilely tuned by the strong interaction between Pt and SnO x .	ptsn	57-61	strawberry notch homolog 1	Homo sapiens	239-242
34487927-1	2022	The nitrogen-doped carbon (NC) coating encapsulating heterostructural Sn/SnO2 microcube powders (Sn/SnO2@NC) are successfully fabricated through hydrothermal, polymerization of hydrogel, and carbonization processes, in which the SnO precursor powders exhibit regular microcube structure and uniform size distribution in the presence of optimized N2H4 H2O (3.0 mL of 1.0 mol/L).	12-nitrocamptothecin	27-29	strawberry notch homolog 1	Homo sapiens	100-103
34788502-5	2022	Using this route, the alloying of Pt-Sn and formation of PtSn-SnO x interfaces can simultaneously be achieved, and the coverage of SnO x thin films on PtSn alloy nanoparticles can be facilely tuned by the strong interaction between Pt and SnO x .	ptsn	151-155	strawberry notch homolog 1	Homo sapiens	131-134
34788502-5	2022	Using this route, the alloying of Pt-Sn and formation of PtSn-SnO x interfaces can simultaneously be achieved, and the coverage of SnO x thin films on PtSn alloy nanoparticles can be facilely tuned by the strong interaction between Pt and SnO x .	ptsn	151-155	strawberry notch homolog 1	Homo sapiens	239-242
34788502-5	2022	Using this route, the alloying of Pt-Sn and formation of PtSn-SnO x interfaces can simultaneously be achieved, and the coverage of SnO x thin films on PtSn alloy nanoparticles can be facilely tuned by the strong interaction between Pt and SnO x .	Platinum	232-234	strawberry notch homolog 1	Homo sapiens	62-65
34788502-5	2022	Using this route, the alloying of Pt-Sn and formation of PtSn-SnO x interfaces can simultaneously be achieved, and the coverage of SnO x thin films on PtSn alloy nanoparticles can be facilely tuned by the strong interaction between Pt and SnO x .	Platinum	232-234	strawberry notch homolog 1	Homo sapiens	131-134
34788502-5	2022	Using this route, the alloying of Pt-Sn and formation of PtSn-SnO x interfaces can simultaneously be achieved, and the coverage of SnO x thin films on PtSn alloy nanoparticles can be facilely tuned by the strong interaction between Pt and SnO x .	Platinum	232-234	strawberry notch homolog 1	Homo sapiens	239-242
34788502-7	2022	Consequently, the H-PtSn/SnO x /CNT-2 catalyst with an optimized PtSn-SnO x interface showed significantly improved performances toward the ethanol oxidation reaction (825 mA mg Pt -1 ).	ptsn	20-24	strawberry notch homolog 1	Homo sapiens	25-28
34788502-7	2022	Consequently, the H-PtSn/SnO x /CNT-2 catalyst with an optimized PtSn-SnO x interface showed significantly improved performances toward the ethanol oxidation reaction (825 mA mg Pt -1 ).	ptsn	20-24	strawberry notch homolog 1	Homo sapiens	70-73
34788502-7	2022	Consequently, the H-PtSn/SnO x /CNT-2 catalyst with an optimized PtSn-SnO x interface showed significantly improved performances toward the ethanol oxidation reaction (825 mA mg Pt -1 ).	ptsn	65-69	strawberry notch homolog 1	Homo sapiens	25-28
34788502-7	2022	Consequently, the H-PtSn/SnO x /CNT-2 catalyst with an optimized PtSn-SnO x interface showed significantly improved performances toward the ethanol oxidation reaction (825 mA mg Pt -1 ).	ptsn	65-69	strawberry notch homolog 1	Homo sapiens	70-73
34788502-7	2022	Consequently, the H-PtSn/SnO x /CNT-2 catalyst with an optimized PtSn-SnO x interface showed significantly improved performances toward the ethanol oxidation reaction (825 mA mg Pt -1 ).	Ethanol	140-147	strawberry notch homolog 1	Homo sapiens	25-28
34788502-7	2022	Consequently, the H-PtSn/SnO x /CNT-2 catalyst with an optimized PtSn-SnO x interface showed significantly improved performances toward the ethanol oxidation reaction (825 mA mg Pt -1 ).	Ethanol	140-147	strawberry notch homolog 1	Homo sapiens	70-73
34894647-0	2021	Effect of Defects on Optical, Electronic, and Interface Properties of NiO/SnO2 Heterostructures: Dual-Functional Solar Photocatalytic H2 Production and RhB Degradation.	nio	70-73	strawberry notch homolog 1	Homo sapiens	74-77
34964627-2	2022	Here, ambipolar SnO transistor-based nonvolatile memories with multibit memory behavior (11 storage states, 120 nC state-1) and ultralong retention time (>105 s) are demonstrated for which an Al2O3/two-dimensional Ruddlesden-Popper perovskite (2D PVK) heterostructure dielectric architecture is employed.	Aluminum Oxide	192-197	strawberry notch homolog 1	Homo sapiens	16-19
34894647-0	2021	Effect of Defects on Optical, Electronic, and Interface Properties of NiO/SnO2 Heterostructures: Dual-Functional Solar Photocatalytic H2 Production and RhB Degradation.	Deuterium	134-136	strawberry notch homolog 1	Homo sapiens	74-77
34894647-0	2021	Effect of Defects on Optical, Electronic, and Interface Properties of NiO/SnO2 Heterostructures: Dual-Functional Solar Photocatalytic H2 Production and RhB Degradation.	rhb	152-155	strawberry notch homolog 1	Homo sapiens	74-77
34719921-5	2021	The full swing of voltage-transfer characteristics with a voltage gain of ~10 and a power dissipation of <4 nW for p-SnO/n-SnO2 and ~120 and <2 nW for p-SnO/n-In2O3-CMOS inverters were successfully demonstrated.	n-in2o3	157-164	strawberry notch homolog 1	Homo sapiens	153-156
34280759-0	2021	One-dimensional Ag-CoNi nanocomposites modified with amorphous Sn(OH)2/SnO2 shells for broadband microwave absorption.	ag-coni	16-23	strawberry notch homolog 1	Homo sapiens	71-74
34280759-2	2021	In this work, high aspect-ratio Ag nanowires were decorated with magnetic CoNi nanoparticles via a PVP-induced solvothermal method, and then amorphous Sn(OH)2/SnO2 shells were introduced through an in-situ oxidative hydrolysis method, successfully preparing Ag-CoNi@Sn(OH)2/SnO2 composites.	sn(oh)2	151-158	strawberry notch homolog 1	Homo sapiens	159-162
34280759-2	2021	In this work, high aspect-ratio Ag nanowires were decorated with magnetic CoNi nanoparticles via a PVP-induced solvothermal method, and then amorphous Sn(OH)2/SnO2 shells were introduced through an in-situ oxidative hydrolysis method, successfully preparing Ag-CoNi@Sn(OH)2/SnO2 composites.	ag-coni	258-265	strawberry notch homolog 1	Homo sapiens	159-162
34280759-2	2021	In this work, high aspect-ratio Ag nanowires were decorated with magnetic CoNi nanoparticles via a PVP-induced solvothermal method, and then amorphous Sn(OH)2/SnO2 shells were introduced through an in-situ oxidative hydrolysis method, successfully preparing Ag-CoNi@Sn(OH)2/SnO2 composites.	Tin	266-268	strawberry notch homolog 1	Homo sapiens	159-162
34280759-2	2021	In this work, high aspect-ratio Ag nanowires were decorated with magnetic CoNi nanoparticles via a PVP-induced solvothermal method, and then amorphous Sn(OH)2/SnO2 shells were introduced through an in-situ oxidative hydrolysis method, successfully preparing Ag-CoNi@Sn(OH)2/SnO2 composites.	(oh)2	268-273	strawberry notch homolog 1	Homo sapiens	159-162
34280759-2	2021	In this work, high aspect-ratio Ag nanowires were decorated with magnetic CoNi nanoparticles via a PVP-induced solvothermal method, and then amorphous Sn(OH)2/SnO2 shells were introduced through an in-situ oxidative hydrolysis method, successfully preparing Ag-CoNi@Sn(OH)2/SnO2 composites.	Tin(IV) oxide	274-278	strawberry notch homolog 1	Homo sapiens	159-162
34280759-4	2021	As Ag-CoNi nanocomposites are coated by Sn(OH)2/SnO2 shells, the minimum reflection loss value is decreased from -31.7 dB (10.1 GHz) to -37.8 dB (6.4 GHz), and the maximum effective absorption bandwidth is extended from 3.9 GHz (10.3-14.2 GHz) to 5.8 GHz (10.7-16.5 GHz).	sn(oh)2	40-47	strawberry notch homolog 1	Homo sapiens	48-51
34280759-6	2021	Thus, Ag nanowires modified with CoNi nanoparticles and amorphous Sn(OH)2/SnO2 shells can effectively balance the impedance matching and attenuation capability.	sn(oh)2	66-73	strawberry notch homolog 1	Homo sapiens	74-77
34946648-5	2021	Under simulated sunlight irradiation (280 nm < lambda < 980 nm), SnO2@MCr demonstrated superior photoactivity toward the denitrification of pyridine, a typical NCC.	pyridine	140-148	strawberry notch homolog 1	Homo sapiens	65-68
34611980-0	2021	Ultrasensitive Sensing of Volatile Organic Compounds Using a Cu-Doped SnO2-NiO p-n Heterostructure That Shows Significant Raman Enhancement.	Copper	61-63	strawberry notch homolog 1	Homo sapiens	70-73
34198142-2	2021	The well-designed porous carbon coating offers an attractive advantage compared to the common carbon coatings, namely, it can not only better mitigate the volumetric variation of SnO2 by means of its spongy structure with better flexibility and rich free space, but also accelerate the lithium-ions diffusion by virtue of its open tunnel-like architecture.	Carbon	25-31	strawberry notch homolog 1	Homo sapiens	179-182
34198142-2	2021	The well-designed porous carbon coating offers an attractive advantage compared to the common carbon coatings, namely, it can not only better mitigate the volumetric variation of SnO2 by means of its spongy structure with better flexibility and rich free space, but also accelerate the lithium-ions diffusion by virtue of its open tunnel-like architecture.	Carbon	94-100	strawberry notch homolog 1	Homo sapiens	179-182
34198142-2	2021	The well-designed porous carbon coating offers an attractive advantage compared to the common carbon coatings, namely, it can not only better mitigate the volumetric variation of SnO2 by means of its spongy structure with better flexibility and rich free space, but also accelerate the lithium-ions diffusion by virtue of its open tunnel-like architecture.	Lithium	286-293	strawberry notch homolog 1	Homo sapiens	179-182
34772226-0	2021	Fabrication of a Selective Sensor Amplification Probe Modified with Multi-Component Zn2SnO4/SnO2 Heterostructured Microparticles as a Robust Electrocatalyst for Electrochemical Detection of Antibacterial Drug Secnidazole.	secnidazole	209-220	strawberry notch homolog 1	Homo sapiens	92-95
34937015-0	2022	Highly sensitive voltammetric determination of NADH based on N-CQDs decorated SnO2/ionic liquid/carbon paste electrode.	NAD	47-51	strawberry notch homolog 1	Homo sapiens	78-81
34704441-0	2021	Tin(II) Ureide Complexes: Synthesis, Structural Chemistry, and Evaluation as SnO Precursors.	tin(ii) ureide	0-14	strawberry notch homolog 1	Homo sapiens	77-80
34719921-2	2021	A high-performance p-channel oxide thin-film transistor (TFT) was developed using an atomically thin p-type tin monoxide, SnO channel with a thickness of ~1 nm, which was grown by a vacuum-free, solvent-free, metal-liquid printing process at low temperatures, as low as 250  C in an ambient atmosphere.	Oxides	29-34	strawberry notch homolog 1	Homo sapiens	122-125
34719921-2	2021	A high-performance p-channel oxide thin-film transistor (TFT) was developed using an atomically thin p-type tin monoxide, SnO channel with a thickness of ~1 nm, which was grown by a vacuum-free, solvent-free, metal-liquid printing process at low temperatures, as low as 250  C in an ambient atmosphere.	Tin(II) oxide	108-120	strawberry notch homolog 1	Homo sapiens	122-125
34719921-2	2021	A high-performance p-channel oxide thin-film transistor (TFT) was developed using an atomically thin p-type tin monoxide, SnO channel with a thickness of ~1 nm, which was grown by a vacuum-free, solvent-free, metal-liquid printing process at low temperatures, as low as 250  C in an ambient atmosphere.	Metals	209-214	strawberry notch homolog 1	Homo sapiens	122-125
34719921-3	2021	By performing oxygen-vacancy defect termination for the bulk-channel and back-channel surface of the ultrathin SnO channel, the presented p-channel SnO TFT exhibited good device performances with a reasonable TFT mobility of ~0.47 cm2 V-1 s-1, a high on/off current ratio of ~106, low off current of <10-12 A, and a subthreshold swing of ~2.5 V decade-1, which was improved compared with the conventional p-channel SnO TFTs.	Oxygen	14-20	strawberry notch homolog 1	Homo sapiens	111-114
34719921-3	2021	By performing oxygen-vacancy defect termination for the bulk-channel and back-channel surface of the ultrathin SnO channel, the presented p-channel SnO TFT exhibited good device performances with a reasonable TFT mobility of ~0.47 cm2 V-1 s-1, a high on/off current ratio of ~106, low off current of <10-12 A, and a subthreshold swing of ~2.5 V decade-1, which was improved compared with the conventional p-channel SnO TFTs.	Oxygen	14-20	strawberry notch homolog 1	Homo sapiens	148-151
34719921-3	2021	By performing oxygen-vacancy defect termination for the bulk-channel and back-channel surface of the ultrathin SnO channel, the presented p-channel SnO TFT exhibited good device performances with a reasonable TFT mobility of ~0.47 cm2 V-1 s-1, a high on/off current ratio of ~106, low off current of <10-12 A, and a subthreshold swing of ~2.5 V decade-1, which was improved compared with the conventional p-channel SnO TFTs.	Oxygen	14-20	strawberry notch homolog 1	Homo sapiens	415-418
34719921-4	2021	We also fabricated metal-liquid printing-based n-channel oxide TFTs such as n-channel SnO2 and In2O3-TFTs and developed ultrathin-channel oxide-TFT-based low-power complementary inverter circuits with the developed p-channel SnO TFTs.	Oxides	138-143	strawberry notch homolog 1	Homo sapiens	225-228
34719921-5	2021	The full swing of voltage-transfer characteristics with a voltage gain of ~10 and a power dissipation of <4 nW for p-SnO/n-SnO2 and ~120 and <2 nW for p-SnO/n-In2O3-CMOS inverters were successfully demonstrated.	n-sno2	121-127	strawberry notch homolog 1	Homo sapiens	117-120
34553492-7	2021	The surface of the ZnFe2 O4 /SnO2 helix photoanode is further modified with TiO2 passivation layer and NiFeOx oxygen evolution co-catalyst to achieve one of the best PEC performances among reported ZnFe2 O4 -based photoanodes.	znfe2 o4	19-27	strawberry notch homolog 1	Homo sapiens	29-32
34358983-3	2021	SO42-/SnO2-CS (1.2 wt%) could be used to catalyze CS (75.0 g/L) with MgCl2 (15.0 g/L) to produce furfural (102.3 mM) in the yield of 68.2% for 0.5 h at 170  C in ChCl:EG-water (20:80, v:v).	Magnesium Chloride	69-74	strawberry notch homolog 1	Homo sapiens	6-9
34358983-3	2021	SO42-/SnO2-CS (1.2 wt%) could be used to catalyze CS (75.0 g/L) with MgCl2 (15.0 g/L) to produce furfural (102.3 mM) in the yield of 68.2% for 0.5 h at 170  C in ChCl:EG-water (20:80, v:v).	Furaldehyde	97-105	strawberry notch homolog 1	Homo sapiens	6-9
34358983-3	2021	SO42-/SnO2-CS (1.2 wt%) could be used to catalyze CS (75.0 g/L) with MgCl2 (15.0 g/L) to produce furfural (102.3 mM) in the yield of 68.2% for 0.5 h at 170  C in ChCl:EG-water (20:80, v:v).	Water	170-175	strawberry notch homolog 1	Homo sapiens	6-9
34553492-7	2021	The surface of the ZnFe2 O4 /SnO2 helix photoanode is further modified with TiO2 passivation layer and NiFeOx oxygen evolution co-catalyst to achieve one of the best PEC performances among reported ZnFe2 O4 -based photoanodes.	titanium dioxide	76-80	strawberry notch homolog 1	Homo sapiens	29-32
34553492-7	2021	The surface of the ZnFe2 O4 /SnO2 helix photoanode is further modified with TiO2 passivation layer and NiFeOx oxygen evolution co-catalyst to achieve one of the best PEC performances among reported ZnFe2 O4 -based photoanodes.	nifeox oxygen	103-116	strawberry notch homolog 1	Homo sapiens	29-32
34553492-7	2021	The surface of the ZnFe2 O4 /SnO2 helix photoanode is further modified with TiO2 passivation layer and NiFeOx oxygen evolution co-catalyst to achieve one of the best PEC performances among reported ZnFe2 O4 -based photoanodes.	znfe2 o4 -based photoanodes	198-225	strawberry notch homolog 1	Homo sapiens	29-32
34642714-0	2021	Multiple channels to enhance near-infrared emission from SiO2-SnO2:Er3+ films by Ba2+ ion doping.	Silicon Dioxide	57-61	strawberry notch homolog 1	Homo sapiens	62-65
34835642-2	2021	Fe3O4-SnO2 nanoparticles were prepared by the carboxylation of the pivotal particles (Fe3O4) with an anionic surfactant to immobilize SnO2 nanoparticles.	fe3o4-sno2	0-10	strawberry notch homolog 1	Homo sapiens	134-137
34835642-2	2021	Fe3O4-SnO2 nanoparticles were prepared by the carboxylation of the pivotal particles (Fe3O4) with an anionic surfactant to immobilize SnO2 nanoparticles.	ferryl iron	86-91	strawberry notch homolog 1	Homo sapiens	134-137
34642714-0	2021	Multiple channels to enhance near-infrared emission from SiO2-SnO2:Er3+ films by Ba2+ ion doping.	er3+	67-71	strawberry notch homolog 1	Homo sapiens	62-65
34642714-0	2021	Multiple channels to enhance near-infrared emission from SiO2-SnO2:Er3+ films by Ba2+ ion doping.	N-methyl-valyl-amiclenomycin	81-85	strawberry notch homolog 1	Homo sapiens	62-65
34214560-0	2021	Facile fabrication of bifunctional SnO-NiO heteromixture for efficient electrocatalytic urea and water oxidation in urea-rich waste water.	Urea	88-92	strawberry notch homolog 1	Homo sapiens	35-38
34528045-0	2021	Evaluation of Sn(II) aminoalkoxide precursors for atomic layer deposition of SnO thin films.	sn(ii) aminoalkoxide	14-34	strawberry notch homolog 1	Homo sapiens	77-80
34214560-0	2021	Facile fabrication of bifunctional SnO-NiO heteromixture for efficient electrocatalytic urea and water oxidation in urea-rich waste water.	Water	97-102	strawberry notch homolog 1	Homo sapiens	35-38
34214560-0	2021	Facile fabrication of bifunctional SnO-NiO heteromixture for efficient electrocatalytic urea and water oxidation in urea-rich waste water.	Urea	116-120	strawberry notch homolog 1	Homo sapiens	35-38
34214560-0	2021	Facile fabrication of bifunctional SnO-NiO heteromixture for efficient electrocatalytic urea and water oxidation in urea-rich waste water.	Water	132-137	strawberry notch homolog 1	Homo sapiens	35-38
34214560-2	2021	In this work, we demonstrated SnO decorated with NiO nanocrystal electrocatalyst is successfully synthesized through solvothermal method and well characterized by scanning electron microscope, transmission electron microscope, X-ray diffraction and X-ray photoelectron spectroscopy.	nio	49-52	strawberry notch homolog 1	Homo sapiens	30-33
34214560-3	2021	Physical characterizations confirm that spherical shape of SnO nanoparticles are homogeneously dispersed on the surface of NiO.	nio	123-126	strawberry notch homolog 1	Homo sapiens	59-62
34214560-5	2021	As proposed catalyst to facilitate the rate of urea oxidation reaction can increase by SnO doped NiO catalyst.	Urea	47-51	strawberry notch homolog 1	Homo sapiens	87-90
34214560-5	2021	As proposed catalyst to facilitate the rate of urea oxidation reaction can increase by SnO doped NiO catalyst.	nio	97-100	strawberry notch homolog 1	Homo sapiens	87-90
34214560-6	2021	The urea oxidation on SnO-NiO nanostructured modified electrode exhibits lower onset potential of 1.12 V and enhancement of current with tafel slope of 150 mV dec-1.	Urea	4-8	strawberry notch homolog 1	Homo sapiens	22-25
34214560-6	2021	The urea oxidation on SnO-NiO nanostructured modified electrode exhibits lower onset potential of 1.12 V and enhancement of current with tafel slope of 150 mV dec-1.	nio	26-29	strawberry notch homolog 1	Homo sapiens	22-25
34214560-7	2021	The obtained results demonstrated the synthesized SnO-NiO anode material could be promising electrode for urea-rich containing wastewater remediation and hydrogen production from wastewater.	Urea	106-110	strawberry notch homolog 1	Homo sapiens	50-53
34214560-7	2021	The obtained results demonstrated the synthesized SnO-NiO anode material could be promising electrode for urea-rich containing wastewater remediation and hydrogen production from wastewater.	Hydrogen	154-162	strawberry notch homolog 1	Homo sapiens	50-53
34410096-0	2021	Efficient Photocatalytic Reduction of CO2 to CO Using NiFe2O4@N/C/SnO2 Derived from FeNi Metal-Organic Framework.	Carbon Dioxide	38-41	strawberry notch homolog 1	Homo sapiens	66-69
34410096-0	2021	Efficient Photocatalytic Reduction of CO2 to CO Using NiFe2O4@N/C/SnO2 Derived from FeNi Metal-Organic Framework.	Carbon Monoxide	45-47	strawberry notch homolog 1	Homo sapiens	66-69
34410096-5	2021	The results of photocatalytic experiments indicated that using (Ru(bpy)3)Cl2 6H2O as a photosensitizer and triethanolamine (TEOA) and acetonitrile (MeCN) as sacrificial agents, the catalyst sample was annealed at 450  C (NiFe2O4@N/C/SnO2-450) to afford the highest CO yield from CO2 (2057.41 mumol g-1 h-1).	Carbon Dioxide	279-282	strawberry notch homolog 1	Homo sapiens	233-236
34410096-0	2021	Efficient Photocatalytic Reduction of CO2 to CO Using NiFe2O4@N/C/SnO2 Derived from FeNi Metal-Organic Framework.	nickel ferrite	54-61	strawberry notch homolog 1	Homo sapiens	66-69
34410096-0	2021	Efficient Photocatalytic Reduction of CO2 to CO Using NiFe2O4@N/C/SnO2 Derived from FeNi Metal-Organic Framework.	Nitrogen	62-63	strawberry notch homolog 1	Homo sapiens	66-69
34410096-0	2021	Efficient Photocatalytic Reduction of CO2 to CO Using NiFe2O4@N/C/SnO2 Derived from FeNi Metal-Organic Framework.	Carbon	64-65	strawberry notch homolog 1	Homo sapiens	66-69
34410096-0	2021	Efficient Photocatalytic Reduction of CO2 to CO Using NiFe2O4@N/C/SnO2 Derived from FeNi Metal-Organic Framework.	feni metal	84-94	strawberry notch homolog 1	Homo sapiens	66-69
34410096-5	2021	The results of photocatalytic experiments indicated that using (Ru(bpy)3)Cl2 6H2O as a photosensitizer and triethanolamine (TEOA) and acetonitrile (MeCN) as sacrificial agents, the catalyst sample was annealed at 450  C (NiFe2O4@N/C/SnO2-450) to afford the highest CO yield from CO2 (2057.41 mumol g-1 h-1).	(ru(bpy)3)cl2 6h2o	63-81	strawberry notch homolog 1	Homo sapiens	233-236
34372048-0	2021	Environmentally Friendly Synthesis of Poly(3,4-Ethylenedioxythiophene): Poly(Styrene Sulfonate)/SnO2 Nanocomposites.	poly(3,4-ethylene dioxythiophene)	38-70	strawberry notch homolog 1	Homo sapiens	96-99
33691863-0	2021	Effects of Microwave and Furnace Annealing for P-Type SnO Thin Film Material in Oxygen Ambient.	Oxygen	80-86	strawberry notch homolog 1	Homo sapiens	54-57
33691863-4	2021	For SnO thin films, it is important to adjust the ratio of Sn2+ (SnO P-type) and Sn4+ (SnO2 n-type) in order to modulate the electrical characteristics.	sn4+	81-85	strawberry notch homolog 1	Homo sapiens	4-7
33691863-6	2021	The results show that SnO thin films are optimized at 300  C, 30 minutes furnace annealing, the P-type SnO/SnO2 thin film shows surface mean roughness 0.168 nm, (Sn2+)/(Sn4+) ratio as 0.838, at least 80% transmittance between 380 nm-700 nm visible light.	Tin(IV) oxide	107-111	strawberry notch homolog 1	Homo sapiens	103-106
33691863-6	2021	The results show that SnO thin films are optimized at 300  C, 30 minutes furnace annealing, the P-type SnO/SnO2 thin film shows surface mean roughness 0.168 nm, (Sn2+)/(Sn4+) ratio as 0.838, at least 80% transmittance between 380 nm-700 nm visible light.	sn4+	169-173	strawberry notch homolog 1	Homo sapiens	103-106
34739779-0	2021	Efficient Conversion of Levulinic Acid to Methyl Levulinate Over SO2-4/SnO2 Nanocatalysts.	levulinic acid	24-38	strawberry notch homolog 1	Homo sapiens	71-74
34209012-0	2021	Photocatalytic Activity of Cu2S/WO3 and Cu2S/SnO2 Heterostructures for Indoor Air Treatment.	Copper(I) sulfide	40-44	strawberry notch homolog 1	Homo sapiens	45-48
34251174-7	2021	This species has a unique geometry involving a large displacement of surface Sn, forcing it to attain the coordination resembling that of Sn2+ in SnO, which seems necessary to stabilize O2- and activate metal-oxide surfaces for gas sensing.	Tin	77-79	strawberry notch homolog 1	Homo sapiens	146-149
34251174-7	2021	This species has a unique geometry involving a large displacement of surface Sn, forcing it to attain the coordination resembling that of Sn2+ in SnO, which seems necessary to stabilize O2- and activate metal-oxide surfaces for gas sensing.	Tin(2+)	138-142	strawberry notch homolog 1	Homo sapiens	146-149
34251174-7	2021	This species has a unique geometry involving a large displacement of surface Sn, forcing it to attain the coordination resembling that of Sn2+ in SnO, which seems necessary to stabilize O2- and activate metal-oxide surfaces for gas sensing.	Oxygen	186-188	strawberry notch homolog 1	Homo sapiens	146-149
34251174-7	2021	This species has a unique geometry involving a large displacement of surface Sn, forcing it to attain the coordination resembling that of Sn2+ in SnO, which seems necessary to stabilize O2- and activate metal-oxide surfaces for gas sensing.	metal-oxide	203-214	strawberry notch homolog 1	Homo sapiens	146-149
34739779-0	2021	Efficient Conversion of Levulinic Acid to Methyl Levulinate Over SO2-4/SnO2 Nanocatalysts.	methyl levulinate	42-59	strawberry notch homolog 1	Homo sapiens	71-74
34739779-0	2021	Efficient Conversion of Levulinic Acid to Methyl Levulinate Over SO2-4/SnO2 Nanocatalysts.	so2-4	65-70	strawberry notch homolog 1	Homo sapiens	71-74
34739779-6	2021	Among them, as prepared 6.9% SO2-4 /SnO2 catalyst exhibits the highest conversation of levulinic acid (98%) and more selectivity towards methyl levulinate (100%).	so2-4	29-34	strawberry notch homolog 1	Homo sapiens	36-39
34739779-6	2021	Among them, as prepared 6.9% SO2-4 /SnO2 catalyst exhibits the highest conversation of levulinic acid (98%) and more selectivity towards methyl levulinate (100%).	levulinic acid	87-101	strawberry notch homolog 1	Homo sapiens	36-39
34739779-6	2021	Among them, as prepared 6.9% SO2-4 /SnO2 catalyst exhibits the highest conversation of levulinic acid (98%) and more selectivity towards methyl levulinate (100%).	methyl levulinate	137-154	strawberry notch homolog 1	Homo sapiens	36-39
35439494-0	2022	An improved electrochemical sensor based on triton X-100 functionalized SnO2 nanoparticles for ultrasensitive determination of cadmium.	Cadmium	127-134	strawberry notch homolog 1	Homo sapiens	72-75
35231478-0	2022	Electrocatalytic oxidation of low concentration cefotaxime sodium wastewater using Ti/SnO2-RuO2 electrode: Feasibility analysis and degradation mechanism.	Cefotaxime	48-65	strawberry notch homolog 1	Homo sapiens	86-89
35231478-0	2022	Electrocatalytic oxidation of low concentration cefotaxime sodium wastewater using Ti/SnO2-RuO2 electrode: Feasibility analysis and degradation mechanism.	Titanium	83-85	strawberry notch homolog 1	Homo sapiens	86-89
35231478-0	2022	Electrocatalytic oxidation of low concentration cefotaxime sodium wastewater using Ti/SnO2-RuO2 electrode: Feasibility analysis and degradation mechanism.	ruthenium dioxide	91-95	strawberry notch homolog 1	Homo sapiens	86-89
35231478-7	2022	Therefore, the electrocatalytic oxidation of Ti/SnO2-RuO2 electrode was a clean and efficient technology, which could be widely used in the treatment of CFX wastewater.	Titanium	45-47	strawberry notch homolog 1	Homo sapiens	48-51
35231478-7	2022	Therefore, the electrocatalytic oxidation of Ti/SnO2-RuO2 electrode was a clean and efficient technology, which could be widely used in the treatment of CFX wastewater.	ruthenium dioxide	53-57	strawberry notch homolog 1	Homo sapiens	48-51
35580198-0	2022	Thionitrite (SNO-) and Perthionitrite (SSNO-) are Simple Synthons for Nitrosylated Iron Sulfur Clusters.	thionitrite	0-11	strawberry notch homolog 1	Homo sapiens	13-16
35522905-2	2022	Since the balanced ambipolarity is significant, a boron-incorporated SnO (SnO:B) oxide semiconductor channel was newly developed to improve the ambipolar charge transports by reducing the subgap defect density, which was reduced to less than 1017 cm-3.	Boron	50-55	strawberry notch homolog 1	Homo sapiens	69-72
35522905-2	2022	Since the balanced ambipolarity is significant, a boron-incorporated SnO (SnO:B) oxide semiconductor channel was newly developed to improve the ambipolar charge transports by reducing the subgap defect density, which was reduced to less than 1017 cm-3.	Boron	50-55	strawberry notch homolog 1	Homo sapiens	74-79
35522905-2	2022	Since the balanced ambipolarity is significant, a boron-incorporated SnO (SnO:B) oxide semiconductor channel was newly developed to improve the ambipolar charge transports by reducing the subgap defect density, which was reduced to less than 1017 cm-3.	Oxides	81-86	strawberry notch homolog 1	Homo sapiens	69-72
35522905-2	2022	Since the balanced ambipolarity is significant, a boron-incorporated SnO (SnO:B) oxide semiconductor channel was newly developed to improve the ambipolar charge transports by reducing the subgap defect density, which was reduced to less than 1017 cm-3.	Oxides	81-86	strawberry notch homolog 1	Homo sapiens	74-79
35580198-0	2022	Thionitrite (SNO-) and Perthionitrite (SSNO-) are Simple Synthons for Nitrosylated Iron Sulfur Clusters.	iron sulfur	83-94	strawberry notch homolog 1	Homo sapiens	13-16
35580198-2	2022	We report here that simple Fe 2+ ions, such as those that are bioavailable in the labile iron pool (LIP), react with thionitrite (SNO - ) and perthionitrite (SSNO - ) to yield the dinitrosyl iron complex (Fe(NO) 2 (S 5 )) - .	Iron	27-29	strawberry notch homolog 1	Homo sapiens	130-133
35580198-2	2022	We report here that simple Fe 2+ ions, such as those that are bioavailable in the labile iron pool (LIP), react with thionitrite (SNO - ) and perthionitrite (SSNO - ) to yield the dinitrosyl iron complex (Fe(NO) 2 (S 5 )) - .	Iron	89-93	strawberry notch homolog 1	Homo sapiens	130-133
35580198-2	2022	We report here that simple Fe 2+ ions, such as those that are bioavailable in the labile iron pool (LIP), react with thionitrite (SNO - ) and perthionitrite (SSNO - ) to yield the dinitrosyl iron complex (Fe(NO) 2 (S 5 )) - .	thionitrite	117-128	strawberry notch homolog 1	Homo sapiens	130-133
35580198-2	2022	We report here that simple Fe 2+ ions, such as those that are bioavailable in the labile iron pool (LIP), react with thionitrite (SNO - ) and perthionitrite (SSNO - ) to yield the dinitrosyl iron complex (Fe(NO) 2 (S 5 )) - .	Iron	191-195	strawberry notch homolog 1	Homo sapiens	130-133
35580198-2	2022	We report here that simple Fe 2+ ions, such as those that are bioavailable in the labile iron pool (LIP), react with thionitrite (SNO - ) and perthionitrite (SSNO - ) to yield the dinitrosyl iron complex (Fe(NO) 2 (S 5 )) - .	flubendiamide	205-211	strawberry notch homolog 1	Homo sapiens	130-133
35580198-3	2022	In the reaction of FeCl 2 with SNO - we were also able to isolate the unstable intermediate hydrosulfido mononitrosyl iron complex (FeCl 2 (NO)(SH)) - , which was characterized by X-ray crystallography.	fecl 2	19-25	strawberry notch homolog 1	Homo sapiens	31-34
35580198-3	2022	In the reaction of FeCl 2 with SNO - we were also able to isolate the unstable intermediate hydrosulfido mononitrosyl iron complex (FeCl 2 (NO)(SH)) - , which was characterized by X-ray crystallography.	hydrosulfido mononitrosyl iron complex	92-130	strawberry notch homolog 1	Homo sapiens	31-34
35580198-3	2022	In the reaction of FeCl 2 with SNO - we were also able to isolate the unstable intermediate hydrosulfido mononitrosyl iron complex (FeCl 2 (NO)(SH)) - , which was characterized by X-ray crystallography.	fecl 2 (no)	132-143	strawberry notch homolog 1	Homo sapiens	31-34
35313297-2	2022	In this work, three-dimensional semiconductor BiVO4 nanoparticles decorated hierarchical TiO2/SnO2 arrays (BiVO4@TiO2/SnO2) were applied as photocathode in Zn-iodine redox flow batteries (ZIRFBs) for the realization of efficient photo-assisted charge/discharge process.	bismuth vanadium tetraoxide	107-112	strawberry notch homolog 1	Homo sapiens	94-97
35548976-3	2022	Here, we propose a heterostructure-based design using a MoSe2/SnO2 composite for achieving sensitive and selective detection of ethyl mercaptan at room temperature.	mose2	56-61	strawberry notch homolog 1	Homo sapiens	62-65
35548976-3	2022	Here, we propose a heterostructure-based design using a MoSe2/SnO2 composite for achieving sensitive and selective detection of ethyl mercaptan at room temperature.	ethanethiol	128-143	strawberry notch homolog 1	Homo sapiens	62-65
35548976-10	2022	The obtained results and superior signal-to-noise ratio indicate that a MoSe2/SnO2-based sensor may be a promising candidate for highly selective and sensitive detection of ethyl mercaptan even below 1 ppm.	mose2	72-77	strawberry notch homolog 1	Homo sapiens	78-81
35548976-10	2022	The obtained results and superior signal-to-noise ratio indicate that a MoSe2/SnO2-based sensor may be a promising candidate for highly selective and sensitive detection of ethyl mercaptan even below 1 ppm.	ethanethiol	173-188	strawberry notch homolog 1	Homo sapiens	78-81
35428033-0	2022	Improved Li storage performance of SnO nanodisc on SnO2Quantum dots embedded carbon matrix.	sno2quantum dots	51-67	strawberry notch homolog 1	Homo sapiens	35-38
35428033-0	2022	Improved Li storage performance of SnO nanodisc on SnO2Quantum dots embedded carbon matrix.	Carbon	77-83	strawberry notch homolog 1	Homo sapiens	35-38
35428033-4	2022	A facile and scalable fabrication of SnO nanodisc decorated on SnO2 quantum dots embedded carbon (SnOx@C) is reported in the present study.	Tin(IV) oxide	63-67	strawberry notch homolog 1	Homo sapiens	37-40
35428033-4	2022	A facile and scalable fabrication of SnO nanodisc decorated on SnO2 quantum dots embedded carbon (SnOx@C) is reported in the present study.	Carbon	90-96	strawberry notch homolog 1	Homo sapiens	37-40
35344324-0	2022	Temperature-Dependent n-p-n Switching and Highly Selective Room-Temperature n-SnSe2/p-SnO/n-SnSe Heterojunction-Based NO2 Gas Sensor.	n-snse2	76-83	strawberry notch homolog 1	Homo sapiens	86-89
35108633-5	2022	In addition, because SnO2@Na:Cs ETL can significantly improve interface contact with the perovskite film and improve its crystallinity, the transport defect state and carrier transport efficiency are significantly improved at the ETL/Perovskite interface.	Cesium	29-31	strawberry notch homolog 1	Homo sapiens	21-24
35108633-5	2022	In addition, because SnO2@Na:Cs ETL can significantly improve interface contact with the perovskite film and improve its crystallinity, the transport defect state and carrier transport efficiency are significantly improved at the ETL/Perovskite interface.	perovskite	89-99	strawberry notch homolog 1	Homo sapiens	21-24
35558834-0	2022	Insight on the effect of Ni and Ni-N co-doping on SnO2 anode materials for lithium-ion batteries.	ni-n	32-36	strawberry notch homolog 1	Homo sapiens	50-53
35377591-0	2022	Optimizing the Microstructure of SnO2-CeO2 Binary Oxide Supported Palladium Catalysts for Efficient and Stable Methane Combustion.	Palladium	66-75	strawberry notch homolog 1	Homo sapiens	33-36
35377591-0	2022	Optimizing the Microstructure of SnO2-CeO2 Binary Oxide Supported Palladium Catalysts for Efficient and Stable Methane Combustion.	Methane	111-118	strawberry notch homolog 1	Homo sapiens	33-36
35332349-3	2022	On the basis of the microstructural observations, SnO2 connected to rGO sheets and naked rGO sheets were observed on the surface of the rGO-SnO2 composite films.	Tin(IV) oxide	140-144	strawberry notch homolog 1	Homo sapiens	50-53
35344324-0	2022	Temperature-Dependent n-p-n Switching and Highly Selective Room-Temperature n-SnSe2/p-SnO/n-SnSe Heterojunction-Based NO2 Gas Sensor.	Nitrogen	90-92	strawberry notch homolog 1	Homo sapiens	86-89
35344324-0	2022	Temperature-Dependent n-p-n Switching and Highly Selective Room-Temperature n-SnSe2/p-SnO/n-SnSe Heterojunction-Based NO2 Gas Sensor.	Nitrogen Dioxide	118-121	strawberry notch homolog 1	Homo sapiens	86-89
35344324-3	2022	We employed the thermal evaporation method to deposit an n-SnSe2/p-SnO/n-SnSe heterojunction and observed a temperature-dependent n-p-n switching NO2 gas sensor with high selectivity working at room temperature (RT).	n-p-n	130-135	strawberry notch homolog 1	Homo sapiens	67-70
35344324-3	2022	We employed the thermal evaporation method to deposit an n-SnSe2/p-SnO/n-SnSe heterojunction and observed a temperature-dependent n-p-n switching NO2 gas sensor with high selectivity working at room temperature (RT).	Nitrogen Dioxide	146-149	strawberry notch homolog 1	Homo sapiens	67-70
35313297-2	2022	In this work, three-dimensional semiconductor BiVO4 nanoparticles decorated hierarchical TiO2/SnO2 arrays (BiVO4@TiO2/SnO2) were applied as photocathode in Zn-iodine redox flow batteries (ZIRFBs) for the realization of efficient photo-assisted charge/discharge process.	titanium dioxide	113-117	strawberry notch homolog 1	Homo sapiens	94-97
35313297-2	2022	In this work, three-dimensional semiconductor BiVO4 nanoparticles decorated hierarchical TiO2/SnO2 arrays (BiVO4@TiO2/SnO2) were applied as photocathode in Zn-iodine redox flow batteries (ZIRFBs) for the realization of efficient photo-assisted charge/discharge process.	Tin(IV) oxide	118-122	strawberry notch homolog 1	Homo sapiens	94-97
35202543-1	2022	The novel tin(II) oxychloride (BMIm)(Sn5O2Cl7) (BMIm = 1-butyl-3-methylimidazolium) is obtained by the room-temperature reaction (25  C) of black SnO and SnCl2 in (BMIm)Cl/SnCl2 as an ionic liquid.	tin(ii) oxychloride	10-29	strawberry notch homolog 1	Homo sapiens	146-149
35238539-0	2022	Interfacial Electron Regulation of Rh Atomic Layer-Decorated SnO2 Heterostructures for Enhancing Electrocatalytic Nitrogen Reduction.	Rhodium	35-37	strawberry notch homolog 1	Homo sapiens	61-64
35238539-0	2022	Interfacial Electron Regulation of Rh Atomic Layer-Decorated SnO2 Heterostructures for Enhancing Electrocatalytic Nitrogen Reduction.	Nitrogen	114-122	strawberry notch homolog 1	Homo sapiens	61-64
35202543-1	2022	The novel tin(II) oxychloride (BMIm)(Sn5O2Cl7) (BMIm = 1-butyl-3-methylimidazolium) is obtained by the room-temperature reaction (25  C) of black SnO and SnCl2 in (BMIm)Cl/SnCl2 as an ionic liquid.	bmim)(sn5o2cl7)	31-46	strawberry notch homolog 1	Homo sapiens	146-149
35202543-1	2022	The novel tin(II) oxychloride (BMIm)(Sn5O2Cl7) (BMIm = 1-butyl-3-methylimidazolium) is obtained by the room-temperature reaction (25  C) of black SnO and SnCl2 in (BMIm)Cl/SnCl2 as an ionic liquid.	1-butyl-3-methylimidazolium	48-52	strawberry notch homolog 1	Homo sapiens	146-149
35202543-1	2022	The novel tin(II) oxychloride (BMIm)(Sn5O2Cl7) (BMIm = 1-butyl-3-methylimidazolium) is obtained by the room-temperature reaction (25  C) of black SnO and SnCl2 in (BMIm)Cl/SnCl2 as an ionic liquid.	1-butyl-3-methylimidazolium	55-82	strawberry notch homolog 1	Homo sapiens	146-149
35202543-1	2022	The novel tin(II) oxychloride (BMIm)(Sn5O2Cl7) (BMIm = 1-butyl-3-methylimidazolium) is obtained by the room-temperature reaction (25  C) of black SnO and SnCl2 in (BMIm)Cl/SnCl2 as an ionic liquid.	stannous chloride	172-177	strawberry notch homolog 1	Homo sapiens	146-149
35073524-3	2022	This paper reports a four-sensor array employing different nano-carbon sensitive layers (bare graphene, SnO2@Graphene, WO3@Graphene, and Au@CNTs).	Carbon	64-70	strawberry notch homolog 1	Homo sapiens	104-107
35218492-0	2022	Ceria-doped SnO2 nanocubes for solar light-driven photocatalytic hydrogen production.	Hydrogen	65-73	strawberry notch homolog 1	Homo sapiens	12-15
35145734-1	2022	Single crystals of Cs2SnSi6O15, dicaesium tin(IV) hexa-silicate, were serendipitously obtained from a CsCl/NaCl flux at 923 K, starting from mixtures of CaO, SnO and TeO2 in a closed silica ampoule.	cs2snsi6o15	19-30	strawberry notch homolog 1	Homo sapiens	158-161
35128555-0	2022	Study on the monolayer dispersion behavior of SnO2 on ZSM-5 for NOx-SCR by C3H6: the remarkable promotional effects of air plasma treatment.	zsm-5	54-59	strawberry notch homolog 1	Homo sapiens	46-49
35128555-0	2022	Study on the monolayer dispersion behavior of SnO2 on ZSM-5 for NOx-SCR by C3H6: the remarkable promotional effects of air plasma treatment.	c3h6	75-79	strawberry notch homolog 1	Homo sapiens	46-49
34983031-0	2022	Fabrication of 3D hierarchical Fe2O3/SnO2 photoanode for enhanced photoelectrochemical performance.	Iron(III) oxide	31-36	strawberry notch homolog 1	Homo sapiens	37-40
34983031-0	2022	Fabrication of 3D hierarchical Fe2O3/SnO2 photoanode for enhanced photoelectrochemical performance.	photoanode	42-52	strawberry notch homolog 1	Homo sapiens	37-40
35055221-0	2022	Characterization of Ti/SnO2 Interface by X-ray Photoelectron Spectroscopy.	Titanium	20-22	strawberry notch homolog 1	Homo sapiens	23-26
35018399-2	2022	From previous studies it is known that SnO can be fabricated through a reaction with H2O, which has low oxidizing power.	Water	85-88	strawberry notch homolog 1	Homo sapiens	39-42
35018399-5	2022	In this study of tincones fabricated with a divalent precursor after a vacuum post-annealing process, the structural rearrangement of the SnO and the benzene ring bonds proceeded to form a SnO-based hybrid 2D structure.	Benzene	150-157	strawberry notch homolog 1	Homo sapiens	189-192
35160864-0	2022	Self-Supported Fibrous Sn/SnO2@C Nanocomposite as Superior Anode Material for Lithium-Ion Batteries.	Lithium	78-85	strawberry notch homolog 1	Homo sapiens	26-29
35145734-1	2022	Single crystals of Cs2SnSi6O15, dicaesium tin(IV) hexa-silicate, were serendipitously obtained from a CsCl/NaCl flux at 923 K, starting from mixtures of CaO, SnO and TeO2 in a closed silica ampoule.	dicaesium tin(iv) hexa-silicate	32-63	strawberry notch homolog 1	Homo sapiens	158-161
7004478-6	1981	In the comparison between Ganda 1.02 and pilocarpine 1% (Sno-Pilo) the mean decrease was 6.34 mmHg with Ganda and 6.13 mmHg with Sno-Pilo.	Sulfisoxazole	26-31	strawberry notch homolog 1	Homo sapiens	129-132
7004478-6	1981	In the comparison between Ganda 1.02 and pilocarpine 1% (Sno-Pilo) the mean decrease was 6.34 mmHg with Ganda and 6.13 mmHg with Sno-Pilo.	Pilocarpine	41-52	strawberry notch homolog 1	Homo sapiens	57-60
7004478-6	1981	In the comparison between Ganda 1.02 and pilocarpine 1% (Sno-Pilo) the mean decrease was 6.34 mmHg with Ganda and 6.13 mmHg with Sno-Pilo.	Pilocarpine	41-52	strawberry notch homolog 1	Homo sapiens	129-132
7004478-6	1981	In the comparison between Ganda 1.02 and pilocarpine 1% (Sno-Pilo) the mean decrease was 6.34 mmHg with Ganda and 6.13 mmHg with Sno-Pilo.	Sulfisoxazole	104-109	strawberry notch homolog 1	Homo sapiens	57-60
20126084-1	1974	The light-induced memory effect in amorphous selenium films is studied by fabricating them into a sort of heterojunction (Se-SnO(2)) so as to be able to apply the bias voltage together with the laser beam irradiation for memory.	Selenium	45-53	strawberry notch homolog 1	Homo sapiens	125-128
18961675-1	1975	Tin(IV) very readily hydrolyses in solution, and forms hydrous tin oxide SnO(2)2.nH(2)O even in rather strongly acidic solution.	stannic oxide	63-72	strawberry notch homolog 1	Homo sapiens	73-76
33268099-0	2021	Nanomixture of 0-D ternary metal oxides (TiO2- SnO2-Al2O3) cooperating with 1-D hydroxyapatite (HAp) nanorods for RhB removal from synthetic wastewater and hydrogen evolution via water splitting.	metal oxides	27-39	strawberry notch homolog 1	Homo sapiens	47-50
33578158-7	2021	The potential for hydroxyl radical generation was measured to be 1.8 V at pH = 12 and 2.6 V at pH = 2.The catalytic degradation rate of methylene blue (MB) follows pseudo first order reaction kinetics, and the reaction constant K value reached 0.02964 -k/min-1, twice as much as that obtained from electrodeposition electrode (Ti/Cu/SnO2-SbOX).	Hydroxyl Radical	18-34	strawberry notch homolog 1	Homo sapiens	333-336
33578158-7	2021	The potential for hydroxyl radical generation was measured to be 1.8 V at pH = 12 and 2.6 V at pH = 2.The catalytic degradation rate of methylene blue (MB) follows pseudo first order reaction kinetics, and the reaction constant K value reached 0.02964 -k/min-1, twice as much as that obtained from electrodeposition electrode (Ti/Cu/SnO2-SbOX).	Methylene Blue	136-150	strawberry notch homolog 1	Homo sapiens	333-336
33578158-7	2021	The potential for hydroxyl radical generation was measured to be 1.8 V at pH = 12 and 2.6 V at pH = 2.The catalytic degradation rate of methylene blue (MB) follows pseudo first order reaction kinetics, and the reaction constant K value reached 0.02964 -k/min-1, twice as much as that obtained from electrodeposition electrode (Ti/Cu/SnO2-SbOX).	Methylene Blue	152-154	strawberry notch homolog 1	Homo sapiens	333-336
33870400-6	2021	To support the proposed mechanisms, we investigated the gas sensor response of SnO2 nanobelts with a higher quantity of oxygen vacancies and correlated the results to the SnO system.	Oxygen	120-126	strawberry notch homolog 1	Homo sapiens	79-82
33535192-3	2021	Under different annealing conditions, the foamed tin is converted to tin oxides with multiple oxidation states (Sn3O4, SnO, and SnO2).	Tin	49-52	strawberry notch homolog 1	Homo sapiens	119-122
33535192-3	2021	Under different annealing conditions, the foamed tin is converted to tin oxides with multiple oxidation states (Sn3O4, SnO, and SnO2).	stannic oxide	69-79	strawberry notch homolog 1	Homo sapiens	119-122
33406508-6	2021	The one-step growth mechanism of SnS2/SnO2could prove a facile process to grow metal oxide-metal sulfide heterostructure.	metal oxide	79-90	strawberry notch homolog 1	Homo sapiens	38-41
33406508-6	2021	The one-step growth mechanism of SnS2/SnO2could prove a facile process to grow metal oxide-metal sulfide heterostructure.	metal sulfide	91-104	strawberry notch homolog 1	Homo sapiens	38-41
33556367-5	2021	The present study evaluated the capacity of the major N-oxide metabolite of SOR (SNO) to inhibit CYP2C8-dependent paclitaxel 6alpha-hydroxylation.	n-oxide	54-61	strawberry notch homolog 1	Homo sapiens	81-84
33855812-0	2021	Pyridine grafted on SnO2-loaded carbon nanotubes acting as cocatalyst for highly efficient electroreduction of CO2.	pyridine	0-8	strawberry notch homolog 1	Homo sapiens	20-23
33855812-0	2021	Pyridine grafted on SnO2-loaded carbon nanotubes acting as cocatalyst for highly efficient electroreduction of CO2.	Carbon	32-38	strawberry notch homolog 1	Homo sapiens	20-23
33855812-0	2021	Pyridine grafted on SnO2-loaded carbon nanotubes acting as cocatalyst for highly efficient electroreduction of CO2.	Carbon Dioxide	111-114	strawberry notch homolog 1	Homo sapiens	20-23
33855812-3	2021	Herein, the grafted pyridine is innovatively coupled with SnO 2 to construct an organic-inorganic composite (SnO 2 /Py-CNTO) for highly efficient CO 2 ER.	pyridine	20-28	strawberry notch homolog 1	Homo sapiens	58-61
33855812-3	2021	Herein, the grafted pyridine is innovatively coupled with SnO 2 to construct an organic-inorganic composite (SnO 2 /Py-CNTO) for highly efficient CO 2 ER.	py-cnto	116-123	strawberry notch homolog 1	Homo sapiens	58-61
33855812-4	2021	The detailed studies show that pyridine and protonated pyridine coexist on the surface of SnO 2 /Py-CNTO, and both play distinctive roles in promoting the selectivity of CO 2 ER.	pyridine	31-39	strawberry notch homolog 1	Homo sapiens	90-93
33855812-4	2021	The detailed studies show that pyridine and protonated pyridine coexist on the surface of SnO 2 /Py-CNTO, and both play distinctive roles in promoting the selectivity of CO 2 ER.	pyridine	55-63	strawberry notch homolog 1	Homo sapiens	90-93
33855812-4	2021	The detailed studies show that pyridine and protonated pyridine coexist on the surface of SnO 2 /Py-CNTO, and both play distinctive roles in promoting the selectivity of CO 2 ER.	py-cnto	97-104	strawberry notch homolog 1	Homo sapiens	90-93
33865111-5	2021	As a result, the optimized MoS2@SnO2-2 heterostructure presents an impressive sensitivity and selectivity for NO2 gas detection at RT.	Nitrogen Dioxide	110-113	strawberry notch homolog 1	Homo sapiens	32-35
33339016-0	2021	SnO2Nanofibers Prepared by Wet Spinning Using an Ordered Porous Alumina Spinneret.	Aluminum Oxide	64-71	strawberry notch homolog 1	Homo sapiens	0-3
33920148-1	2021	In this work, semiconductor tin oxide (II) (SnO) nanoparticles and plates were synthesized at room conditions via a hydrolysis procedure.	tin oxide (ii)	28-42	strawberry notch homolog 1	Homo sapiens	44-47
33920148-4	2021	Thermal treatments induced the oxidation from SnO to SnO2 without formation of intermediate SnOx, as confirmed by thermodiffraction measurements, while by using UV or red laser irradiation the transition from SnO to SnO2 was controlled, assisted by formation of intermediate Sn3O4, as confirmed by Raman spectroscopy.	Tin(IV) oxide	216-220	strawberry notch homolog 1	Homo sapiens	46-49
33920148-6	2021	Finally, a tailored spatial SnO/SnO2 micropatterning was achieved by controlled laser irradiation with potential applicability in optoelectronics and sensing devices.	Tin(IV) oxide	32-36	strawberry notch homolog 1	Homo sapiens	28-31
33556367-5	2021	The present study evaluated the capacity of the major N-oxide metabolite of SOR (SNO) to inhibit CYP2C8-dependent paclitaxel 6alpha-hydroxylation.	Paclitaxel	114-124	strawberry notch homolog 1	Homo sapiens	81-84
33633214-2	2021	Scanning electron microscopy investigation shows the formation of Ag/Au alloys particles during irradiation of Ag-Au bilayer deposited on FTO (SnO2:F) substrate by laser fluency equal to 0.5 J/cm2 or 1.0 J/cm2 with 12 ns laser pulse duration.	Gold	69-71	strawberry notch homolog 1	Homo sapiens	143-146
33739099-0	2021	CsPbI3NC-Sensitized SnO2/Multiple-Walled Carbon Nanotube Self-Assembled Nanomaterials with Highly Selective and Sensitive NH3 Sensing Performance at Room Temperature.	Ammonia	122-125	strawberry notch homolog 1	Homo sapiens	20-23
33264752-5	2021	The sensing mechanism of the sensor relies on the reaction of ethanol vapor and chemisorbed oxygen species in which the reaction rate increases due to an abundance of the chemisorbed oxygen within n-p heterojunctions of SnO2-rGO.	Ethanol	62-69	strawberry notch homolog 1	Homo sapiens	220-223
33264752-5	2021	The sensing mechanism of the sensor relies on the reaction of ethanol vapor and chemisorbed oxygen species in which the reaction rate increases due to an abundance of the chemisorbed oxygen within n-p heterojunctions of SnO2-rGO.	Oxygen	92-98	strawberry notch homolog 1	Homo sapiens	220-223
33264752-5	2021	The sensing mechanism of the sensor relies on the reaction of ethanol vapor and chemisorbed oxygen species in which the reaction rate increases due to an abundance of the chemisorbed oxygen within n-p heterojunctions of SnO2-rGO.	Oxygen	183-189	strawberry notch homolog 1	Homo sapiens	220-223
33264752-5	2021	The sensing mechanism of the sensor relies on the reaction of ethanol vapor and chemisorbed oxygen species in which the reaction rate increases due to an abundance of the chemisorbed oxygen within n-p heterojunctions of SnO2-rGO.	Neptunium	197-200	strawberry notch homolog 1	Homo sapiens	220-223
33633214-2	2021	Scanning electron microscopy investigation shows the formation of Ag/Au alloys particles during irradiation of Ag-Au bilayer deposited on FTO (SnO2:F) substrate by laser fluency equal to 0.5 J/cm2 or 1.0 J/cm2 with 12 ns laser pulse duration.	Gold	114-116	strawberry notch homolog 1	Homo sapiens	143-146
33458732-0	2021	Quantitative analysis of the synergistic effect of Au nanoparticles on SnO2-rGO nanocomposites for room temperature hydrogen sensing.	Gold	51-53	strawberry notch homolog 1	Homo sapiens	71-74
33507081-4	2021	The underlying physical mechanism is generally applicable and can be extended to other oxide films such as ferroelectric SnO and GeO, thus paving an avenue for future design and fabrication of functional ultrathin devices that are compatible with Si-based technology.	Oxides	87-92	strawberry notch homolog 1	Homo sapiens	121-124
33507081-4	2021	The underlying physical mechanism is generally applicable and can be extended to other oxide films such as ferroelectric SnO and GeO, thus paving an avenue for future design and fabrication of functional ultrathin devices that are compatible with Si-based technology.	Silicon	247-249	strawberry notch homolog 1	Homo sapiens	121-124
33458732-0	2021	Quantitative analysis of the synergistic effect of Au nanoparticles on SnO2-rGO nanocomposites for room temperature hydrogen sensing.	Hydrogen	116-124	strawberry notch homolog 1	Homo sapiens	71-74
33441635-3	2021	Transition metal SnO2 deals with four different active materials i.e., Pure SnO2, SnO2-Pd, SnO2-rGO, and SnO2-Pd/rGO film was controlled by altering the active materials during the active layer deposition.	Metals	11-16	strawberry notch homolog 1	Homo sapiens	17-20
33615157-0	2021	SnO x Atomic Layer Deposition on Bare Perovskite-An Investigation of Initial Growth Dynamics, Interface Chemistry, and Solar Cell Performance.	perovskite	38-48	strawberry notch homolog 1	Homo sapiens	0-3
33615157-1	2021	High-end organic-inorganic lead halide perovskite semitransparent p-i-n solar cells for tandem applications use a phenyl-C61-butyric acid methyl ester (PCBM)/atomic layer deposition (ALD)-SnO x electron transport layer stack.	perovskite	39-49	strawberry notch homolog 1	Homo sapiens	188-191
33615157-3	2021	A direct ALD-SnO x exposure was therefore suggested to form a nonideal perovskite/SnO x interface that acts as a transport barrier for the light-generated current.	perovskite	71-81	strawberry notch homolog 1	Homo sapiens	13-16
33615157-8	2021	The chemical environments of the buried interface were analyzed by soft and hard X-ray photoelectron spectroscopy for a sample with 50 ALD cycles of SnO x on the perovskite.	perovskite	162-172	strawberry notch homolog 1	Homo sapiens	149-152
33498992-0	2021	A Highly Sensitive Room Temperature CO2 Gas Sensor Based on SnO2-rGO Hybrid Composite.	Carbon Dioxide	36-39	strawberry notch homolog 1	Homo sapiens	60-63
33498992-6	2021	The synergistic effect can explain the obtained hybrid gas sensor"s prominent sensing properties between SnO2 and rGO that provide excellent charge transport capability and an abundance of sensing sites.	rgo	114-117	strawberry notch homolog 1	Homo sapiens	105-108
33441635-3	2021	Transition metal SnO2 deals with four different active materials i.e., Pure SnO2, SnO2-Pd, SnO2-rGO, and SnO2-Pd/rGO film was controlled by altering the active materials during the active layer deposition.	Tin(IV) oxide	76-80	strawberry notch homolog 1	Homo sapiens	17-20
33401635-5	2021	Secondary ion mass spectrometry analysis revealed that the excellent device integrity was strongly related to process temperature, because the HfO2/SnO interface and related muFE were degraded by Sn and Hf inter-diffusion at an elevated temperature due to weak Sn-O bond enthalpy.	hafnium oxide	143-147	strawberry notch homolog 1	Homo sapiens	148-151
33401635-6	2021	Oxygen content during process is also crucial because the hole-conductive p-type SnO channel is oxidized into oxygen-rich n-type SnO2 to demote the device performance.	Oxygen	110-116	strawberry notch homolog 1	Homo sapiens	81-84
33401635-6	2021	Oxygen content during process is also crucial because the hole-conductive p-type SnO channel is oxidized into oxygen-rich n-type SnO2 to demote the device performance.	Oxygen	0-6	strawberry notch homolog 1	Homo sapiens	81-84
33401635-6	2021	Oxygen content during process is also crucial because the hole-conductive p-type SnO channel is oxidized into oxygen-rich n-type SnO2 to demote the device performance.	Tin(IV) oxide	129-133	strawberry notch homolog 1	Homo sapiens	81-84
33130391-0	2021	Effect of formaldehyde properties on SnO2 clusters gas sensitivity: A DFT study.	Formaldehyde	10-22	strawberry notch homolog 1	Homo sapiens	37-40
33113663-0	2020	Thermal decomposition based fabrication of dimensionally stable Ti/SnO2-RuO2 anode for highly efficient electrocatalytic degradation of alizarin cyanin green.	Titanium	64-66	strawberry notch homolog 1	Homo sapiens	67-70
33419262-0	2020	Self-Assembled Few-Layered MoS2 on SnO2 Anode for Enhancing Lithium-Ion Storage.	Lithium	60-67	strawberry notch homolog 1	Homo sapiens	35-38
33276659-2	2020	In the integrated cathode, Pt nanoparticles were deposited uniformly with a small particle size on the SnO2@C/CP support.	Platinum	27-29	strawberry notch homolog 1	Homo sapiens	103-106
33113663-0	2020	Thermal decomposition based fabrication of dimensionally stable Ti/SnO2-RuO2 anode for highly efficient electrocatalytic degradation of alizarin cyanin green.	ruthenium dioxide	72-76	strawberry notch homolog 1	Homo sapiens	67-70
33113663-0	2020	Thermal decomposition based fabrication of dimensionally stable Ti/SnO2-RuO2 anode for highly efficient electrocatalytic degradation of alizarin cyanin green.	Acid Green 25	136-157	strawberry notch homolog 1	Homo sapiens	67-70
33113663-2	2020	The morphology, crystal structure and composition of Ti/SnO2-RuO2 electrode are characterized by scanning electron microscopy (SEM), X-ray diffraction (XRD) and X-ray fluorescence spectroscopy (XRF), respectively.	ruthenium dioxide	61-65	strawberry notch homolog 1	Homo sapiens	56-59
33113663-7	2020	The excellent electrochemical activity demonstrates that the Ti/SnO2-RuO2 electrode presents a favorable application prospect in the electrochemical treatment of anthraquinone dye wastewater.	Titanium	61-63	strawberry notch homolog 1	Homo sapiens	64-67
33113663-7	2020	The excellent electrochemical activity demonstrates that the Ti/SnO2-RuO2 electrode presents a favorable application prospect in the electrochemical treatment of anthraquinone dye wastewater.	Anthraquinones	162-175	strawberry notch homolog 1	Homo sapiens	64-67
33085477-2	2020	The ability to easily modify S-, N-, and O-containing cyclooctynes (SNO-OCTs) enables electronic tuning of various SNO-OCTs to influence their cycloaddition rates with Type I-III dipoles.	s-, n-, and o-containing cyclooctynes	29-66	strawberry notch homolog 1	Homo sapiens	68-71
31762365-2	2020	We therefore developed an S-nitrosylated L-serine-modified polyamidoamine dendrimer (SNO-Ser-PAMAM), in which multiple S-nitrosothiols (NO donors) were covalently bound to L-serine-modified dendrimer, as a kidney-targeting NO donor.	(2,2'-L-serine)-gramicidin S	26-49	strawberry notch homolog 1	Homo sapiens	85-88
31762365-2	2020	We therefore developed an S-nitrosylated L-serine-modified polyamidoamine dendrimer (SNO-Ser-PAMAM), in which multiple S-nitrosothiols (NO donors) were covalently bound to L-serine-modified dendrimer, as a kidney-targeting NO donor.	Poly(amidoamine)	59-73	strawberry notch homolog 1	Homo sapiens	85-88
31762365-2	2020	We therefore developed an S-nitrosylated L-serine-modified polyamidoamine dendrimer (SNO-Ser-PAMAM), in which multiple S-nitrosothiols (NO donors) were covalently bound to L-serine-modified dendrimer, as a kidney-targeting NO donor.	S-Nitrosothiols	119-134	strawberry notch homolog 1	Homo sapiens	85-88
31762365-2	2020	We therefore developed an S-nitrosylated L-serine-modified polyamidoamine dendrimer (SNO-Ser-PAMAM), in which multiple S-nitrosothiols (NO donors) were covalently bound to L-serine-modified dendrimer, as a kidney-targeting NO donor.	cholecystokinin C-terminal flanking peptide	41-49	strawberry notch homolog 1	Homo sapiens	85-88
31762365-4	2020	Furthermore, single photon emission computed tomography/computed tomography (SPECT/CT) imaging study showed that 111In-SNO-Ser-PAMAM specifically accumulated in the renal cortex after intravenous injection.	seryl-seryl-seryl-arginine	123-126	strawberry notch homolog 1	Homo sapiens	119-122
31762365-4	2020	Furthermore, single photon emission computed tomography/computed tomography (SPECT/CT) imaging study showed that 111In-SNO-Ser-PAMAM specifically accumulated in the renal cortex after intravenous injection.	PEG-PAMAM	127-132	strawberry notch homolog 1	Homo sapiens	119-122
31762365-5	2020	SNO-Ser-PAMAM gradually released NO over a day in plasma, indicating that SNO-Ser-PAMAM would show sustained release of NO in vivo.	seryl-seryl-seryl-arginine	4-7	strawberry notch homolog 1	Homo sapiens	0-3
31762365-5	2020	SNO-Ser-PAMAM gradually released NO over a day in plasma, indicating that SNO-Ser-PAMAM would show sustained release of NO in vivo.	seryl-seryl-seryl-arginine	4-7	strawberry notch homolog 1	Homo sapiens	74-77
31762365-5	2020	SNO-Ser-PAMAM gradually released NO over a day in plasma, indicating that SNO-Ser-PAMAM would show sustained release of NO in vivo.	PEG-PAMAM	8-13	strawberry notch homolog 1	Homo sapiens	0-3
31762365-5	2020	SNO-Ser-PAMAM gradually released NO over a day in plasma, indicating that SNO-Ser-PAMAM would show sustained release of NO in vivo.	PEG-PAMAM	8-13	strawberry notch homolog 1	Homo sapiens	74-77
31762365-7	2020	These results indicate that SNO-Ser-PAMAM is a promising kidney-targeting NO donor for the efficient prevention of renal ischemia/reperfusion injury.	seryl-seryl-seryl-arginine	32-35	strawberry notch homolog 1	Homo sapiens	28-31
31762365-7	2020	These results indicate that SNO-Ser-PAMAM is a promising kidney-targeting NO donor for the efficient prevention of renal ischemia/reperfusion injury.	PEG-PAMAM	36-41	strawberry notch homolog 1	Homo sapiens	28-31
32711646-0	2020	Fabrication and Characterization of SnO-Cu2O Mixed Metal Oxide Thin Films for Photoelectrochemical Applications.	cuprous oxide	40-44	strawberry notch homolog 1	Homo sapiens	36-39
32711646-0	2020	Fabrication and Characterization of SnO-Cu2O Mixed Metal Oxide Thin Films for Photoelectrochemical Applications.	metal oxide	51-62	strawberry notch homolog 1	Homo sapiens	36-39
32711646-1	2020	Herein, we report the synthesis of SnO, Cu2O and SnO-Cu2O mixed oxide thin films on fluorinedoped tin oxide (FTO) substrate by Aerosol-Assisted Chemical Vapour Deposition (AACVD) process using [Cu (dmae)2(H2O)] and [Sn (dmae) (OAc)]2 as molecular precursors for SnO and Cu2O, respectively at 400  C. The X-ray diffraction (XRD) pattern can be ascribed to the tetragonal phase of SnO crystals with space group P4 and cubic phase of Cu2O crystals with space group Pn- 3m/nmm, respectively.	Water	205-208	strawberry notch homolog 1	Homo sapiens	35-38
32711646-1	2020	Herein, we report the synthesis of SnO, Cu2O and SnO-Cu2O mixed oxide thin films on fluorinedoped tin oxide (FTO) substrate by Aerosol-Assisted Chemical Vapour Deposition (AACVD) process using [Cu (dmae)2(H2O)] and [Sn (dmae) (OAc)]2 as molecular precursors for SnO and Cu2O, respectively at 400  C. The X-ray diffraction (XRD) pattern can be ascribed to the tetragonal phase of SnO crystals with space group P4 and cubic phase of Cu2O crystals with space group Pn- 3m/nmm, respectively.	Water	205-208	strawberry notch homolog 1	Homo sapiens	49-52
32711646-1	2020	Herein, we report the synthesis of SnO, Cu2O and SnO-Cu2O mixed oxide thin films on fluorinedoped tin oxide (FTO) substrate by Aerosol-Assisted Chemical Vapour Deposition (AACVD) process using [Cu (dmae)2(H2O)] and [Sn (dmae) (OAc)]2 as molecular precursors for SnO and Cu2O, respectively at 400  C. The X-ray diffraction (XRD) pattern can be ascribed to the tetragonal phase of SnO crystals with space group P4 and cubic phase of Cu2O crystals with space group Pn- 3m/nmm, respectively.	Water	205-208	strawberry notch homolog 1	Homo sapiens	49-52
32711646-1	2020	Herein, we report the synthesis of SnO, Cu2O and SnO-Cu2O mixed oxide thin films on fluorinedoped tin oxide (FTO) substrate by Aerosol-Assisted Chemical Vapour Deposition (AACVD) process using [Cu (dmae)2(H2O)] and [Sn (dmae) (OAc)]2 as molecular precursors for SnO and Cu2O, respectively at 400  C. The X-ray diffraction (XRD) pattern can be ascribed to the tetragonal phase of SnO crystals with space group P4 and cubic phase of Cu2O crystals with space group Pn- 3m/nmm, respectively.	Water	205-208	strawberry notch homolog 1	Homo sapiens	49-52
32711646-2	2020	The surface morphology characteristics of SnO, Cu2O and SnO-Cu2Omixed oxide have been investigated using Field Emission Scanning Electron Microscope (FESEM) which revealed that the SnO was grown homogeneously in cubical shape while Cu2O possess nano balls shaped morphologies.	cu2omixed oxide	60-75	strawberry notch homolog 1	Homo sapiens	56-59
32711646-2	2020	The surface morphology characteristics of SnO, Cu2O and SnO-Cu2Omixed oxide have been investigated using Field Emission Scanning Electron Microscope (FESEM) which revealed that the SnO was grown homogeneously in cubical shape while Cu2O possess nano balls shaped morphologies.	cu2omixed oxide	60-75	strawberry notch homolog 1	Homo sapiens	56-59
32711646-2	2020	The surface morphology characteristics of SnO, Cu2O and SnO-Cu2Omixed oxide have been investigated using Field Emission Scanning Electron Microscope (FESEM) which revealed that the SnO was grown homogeneously in cubical shape while Cu2O possess nano balls shaped morphologies.	cuprous oxide	60-64	strawberry notch homolog 1	Homo sapiens	56-59
32711646-2	2020	The surface morphology characteristics of SnO, Cu2O and SnO-Cu2Omixed oxide have been investigated using Field Emission Scanning Electron Microscope (FESEM) which revealed that the SnO was grown homogeneously in cubical shape while Cu2O possess nano balls shaped morphologies.	cuprous oxide	60-64	strawberry notch homolog 1	Homo sapiens	56-59
32711646-3	2020	The UV band gap values of SnO-Cu2O mixed oxide thin film was found to be 2.6 eV appropriate for photoelectrochemical (PEC) applications.	cuprous oxide	30-34	strawberry notch homolog 1	Homo sapiens	26-29
32711646-3	2020	The UV band gap values of SnO-Cu2O mixed oxide thin film was found to be 2.6 eV appropriate for photoelectrochemical (PEC) applications.	Oxides	41-46	strawberry notch homolog 1	Homo sapiens	26-29
33085477-2	2020	The ability to easily modify S-, N-, and O-containing cyclooctynes (SNO-OCTs) enables electronic tuning of various SNO-OCTs to influence their cycloaddition rates with Type I-III dipoles.	s-, n-, and o-containing cyclooctynes	29-66	strawberry notch homolog 1	Homo sapiens	115-118
33085477-3	2020	As opposed to optimizations based on just one specific dipole class, the electrophilicity of the alkynes in SNO-OCTs can be manipulated to achieve divergent reactivities and furnish mutually orthogonal dual ligation systems.	Alkynes	97-104	strawberry notch homolog 1	Homo sapiens	108-111
33085477-4	2020	Significant reaction rate enhancements of a difluorinated SNO-OCT derivative, as compared to the parent scaffold, were noted, with the second-order rate constant in cycloadditions with diazoacetamides exceeding 5.13 M-1 s-1.	diazoacetamide	185-200	strawberry notch homolog 1	Homo sapiens	58-61
33126463-5	2020	The inserted SiO2 layer is crucial for decreasing the charged defect scattering in the HfO2 and HfO2/SnO2 interfaces to increase the mobility.	Silicon Dioxide	13-17	strawberry notch homolog 1	Homo sapiens	101-104
32604577-0	2020	Effects of Thin-Film Thickness on Sensing Properties of SnO2-Based Gas Sensors for the Detection of H2S Gas at ppm Levels.	Deuterium	100-103	strawberry notch homolog 1	Homo sapiens	56-59
33126463-5	2020	The inserted SiO2 layer is crucial for decreasing the charged defect scattering in the HfO2 and HfO2/SnO2 interfaces to increase the mobility.	hafnium oxide	96-100	strawberry notch homolog 1	Homo sapiens	101-104
33008074-0	2020	Effects of Capping Layers with Different Metals on Electrical Performance and Stability of p-Channel SnO Thin-Film Transistors.	Metals	41-47	strawberry notch homolog 1	Homo sapiens	101-104
32966499-1	2020	In this paper, we present a novel room temperature (RT) operated SnO2-ZnO-Fe2O3 based tri-composite analyte sensor with dual behavior having detection ability of up to ~1 ppb with a substantial % response (R) to detect ammonia and ethanol vapors.	Ammonia	219-226	strawberry notch homolog 1	Homo sapiens	65-68
32966499-1	2020	In this paper, we present a novel room temperature (RT) operated SnO2-ZnO-Fe2O3 based tri-composite analyte sensor with dual behavior having detection ability of up to ~1 ppb with a substantial % response (R) to detect ammonia and ethanol vapors.	Ethanol	231-238	strawberry notch homolog 1	Homo sapiens	65-68
32700801-0	2020	Structural design and synthesis of SnO2@C@Co-NC composite as high-performance anode material for lithium-ion batteries.	Lithium	97-104	strawberry notch homolog 1	Homo sapiens	35-38
33017320-0	2020	Twinning in SnO2-based ceramics doped with CoO- and Nb2O5: morphology of multiple twins revealed by electron backscatter diffraction.	coo- and nb2o5	43-57	strawberry notch homolog 1	Homo sapiens	12-15
33008074-3	2020	In contrast, Al-capped SnO TFTs exhibit a lower muFE, higher SS, negatively shifted VTH, and degraded NGBS stability, as compared to pristine TFTs.	Aluminum	13-15	strawberry notch homolog 1	Homo sapiens	23-26
33008074-3	2020	In contrast, Al-capped SnO TFTs exhibit a lower muFE, higher SS, negatively shifted VTH, and degraded NGBS stability, as compared to pristine TFTs.	ngbs	102-106	strawberry notch homolog 1	Homo sapiens	23-26
33008074-4	2020	No significant difference was observed between the electrical performance of the Cr-capped SnO TFT and that of the pristine SnO TFT.	Chromium	81-83	strawberry notch homolog 1	Homo sapiens	91-94
32815956-0	2020	The first-principles study of nH-VSn complex: impurity effects on p-type SnO monolayer.	nh-vsn	30-36	strawberry notch homolog 1	Homo sapiens	73-76
32815956-2	2020	Using the first-principles calculation, we studied the effects of multi-hydrogen-tin/oxygen vacancy complex impurities on the electronic properties of the p-type monolayer SnO.	Hydrogen	72-80	strawberry notch homolog 1	Homo sapiens	172-175
32815956-2	2020	Using the first-principles calculation, we studied the effects of multi-hydrogen-tin/oxygen vacancy complex impurities on the electronic properties of the p-type monolayer SnO.	Tin	81-84	strawberry notch homolog 1	Homo sapiens	172-175
32815956-2	2020	Using the first-principles calculation, we studied the effects of multi-hydrogen-tin/oxygen vacancy complex impurities on the electronic properties of the p-type monolayer SnO.	Oxygen	85-91	strawberry notch homolog 1	Homo sapiens	172-175
32815956-9	2020	Our results indicated that limitation of hydrogen is necessary for the preparation of high-quality p-type two-dimensional SnO, as a small amount of hydrogen produces positive effect on p-type SnO; however, the higher concentration of hydrogen is destructive to the p-type character of monolayer SnO.	Hydrogen	41-49	strawberry notch homolog 1	Homo sapiens	122-125
32815956-9	2020	Our results indicated that limitation of hydrogen is necessary for the preparation of high-quality p-type two-dimensional SnO, as a small amount of hydrogen produces positive effect on p-type SnO; however, the higher concentration of hydrogen is destructive to the p-type character of monolayer SnO.	Hydrogen	148-156	strawberry notch homolog 1	Homo sapiens	122-125
32815956-9	2020	Our results indicated that limitation of hydrogen is necessary for the preparation of high-quality p-type two-dimensional SnO, as a small amount of hydrogen produces positive effect on p-type SnO; however, the higher concentration of hydrogen is destructive to the p-type character of monolayer SnO.	Hydrogen	148-156	strawberry notch homolog 1	Homo sapiens	192-195
32815956-9	2020	Our results indicated that limitation of hydrogen is necessary for the preparation of high-quality p-type two-dimensional SnO, as a small amount of hydrogen produces positive effect on p-type SnO; however, the higher concentration of hydrogen is destructive to the p-type character of monolayer SnO.	Hydrogen	148-156	strawberry notch homolog 1	Homo sapiens	192-195
32815956-9	2020	Our results indicated that limitation of hydrogen is necessary for the preparation of high-quality p-type two-dimensional SnO, as a small amount of hydrogen produces positive effect on p-type SnO; however, the higher concentration of hydrogen is destructive to the p-type character of monolayer SnO.	Hydrogen	148-156	strawberry notch homolog 1	Homo sapiens	122-125
32815956-9	2020	Our results indicated that limitation of hydrogen is necessary for the preparation of high-quality p-type two-dimensional SnO, as a small amount of hydrogen produces positive effect on p-type SnO; however, the higher concentration of hydrogen is destructive to the p-type character of monolayer SnO.	Hydrogen	148-156	strawberry notch homolog 1	Homo sapiens	192-195
32815956-9	2020	Our results indicated that limitation of hydrogen is necessary for the preparation of high-quality p-type two-dimensional SnO, as a small amount of hydrogen produces positive effect on p-type SnO; however, the higher concentration of hydrogen is destructive to the p-type character of monolayer SnO.	Hydrogen	148-156	strawberry notch homolog 1	Homo sapiens	192-195
32674578-0	2020	Mo-doped SnO2 nanoparticles embedded in ultrathin graphite nanosheets as a high reversible capacity, superior rate and long cycle life anode material for lithium-ion batteries.	Graphite	50-58	strawberry notch homolog 1	Homo sapiens	9-12
32452168-3	2020	Herein, a self-controlled SnO 2 layer is successfully fabricated on a direct fluorine-doped tin oxide (FTO) surface via simple and rapid chemical bath deposition.	Fluorine	77-85	strawberry notch homolog 1	Homo sapiens	26-29
32452168-3	2020	Herein, a self-controlled SnO 2 layer is successfully fabricated on a direct fluorine-doped tin oxide (FTO) surface via simple and rapid chemical bath deposition.	stannic oxide	92-101	strawberry notch homolog 1	Homo sapiens	26-29
32452168-3	2020	Herein, a self-controlled SnO 2 layer is successfully fabricated on a direct fluorine-doped tin oxide (FTO) surface via simple and rapid chemical bath deposition.	L 685458	103-106	strawberry notch homolog 1	Homo sapiens	26-29
32452168-6	2020	The hydrolyzed SnO 2 -based PSCs demonstrated a faster ionic charge response time of 2.5 ms in comparison with the 100.5 ms for the hydrolyzed TiO 2 -based hysteric PSCs.	tio 2	143-148	strawberry notch homolog 1	Homo sapiens	15-18
32344383-7	2020	Furthermore, the SnO2 NTs-based transparent photodetectors were as well be integrated with fluorine-doped tin oxide glass and demonstrated a high optical transparency and photosensitivity (~199).	Fluorine	91-99	strawberry notch homolog 1	Homo sapiens	17-20
32344383-7	2020	Furthermore, the SnO2 NTs-based transparent photodetectors were as well be integrated with fluorine-doped tin oxide glass and demonstrated a high optical transparency and photosensitivity (~199).	stannic oxide	106-115	strawberry notch homolog 1	Homo sapiens	17-20
32674578-0	2020	Mo-doped SnO2 nanoparticles embedded in ultrathin graphite nanosheets as a high reversible capacity, superior rate and long cycle life anode material for lithium-ion batteries.	Lithium	154-161	strawberry notch homolog 1	Homo sapiens	9-12
32666563-2	2020	Advances in topological band theories have led to the prediction that the antiperovskite oxide Sr3 SnO is a topological crystalline insulator, a new electronic phase of matter where the conductivity in its (001) crystallographic planes is protected by crystallographic point group symmetries.	antiperovskite oxide	74-94	strawberry notch homolog 1	Homo sapiens	99-102
32639143-9	2020	Moreover, the NO2 sensing properties of the p-SnO/n-ZnO device was investigated under various relative humidity (RH).	Nitrogen Dioxide	14-17	strawberry notch homolog 1	Homo sapiens	46-49
32639143-10	2020	Finally, the NO2 sensing mechanism of the p-SnO/n-ZnO nanowires was proposed and discussed.	Nitrogen Dioxide	13-16	strawberry notch homolog 1	Homo sapiens	44-47
32639143-0	2020	Growth and NO2 Sensing Properties of Biaxial p-SnO/n-ZnO Heterostructured Nanowires.	Nitrogen Dioxide	11-14	strawberry notch homolog 1	Homo sapiens	47-50
32639143-10	2020	Finally, the NO2 sensing mechanism of the p-SnO/n-ZnO nanowires was proposed and discussed.	n-zno	48-53	strawberry notch homolog 1	Homo sapiens	44-47
32639143-4	2020	A possible growth mechanism of the p-SnO/n-ZnO biaxial nanowires was discussed based on the subsequent growth process: the VLS catalyticgrowth of the ZnO nanowire and subsequent epitaxial SnO growth on the sidewall of the pre-grown ZnO nanowire.	n-zno	41-46	strawberry notch homolog 1	Homo sapiens	37-40
32109696-0	2020	Degradation of aqueous cefotaxime in electro-oxidation - electro-Fenton -persulfate system with Ti/CNT/SnO2-Sb-Er anode and Ni@NCNT cathode.	Cefotaxime	23-33	strawberry notch homolog 1	Homo sapiens	103-106
32639143-4	2020	A possible growth mechanism of the p-SnO/n-ZnO biaxial nanowires was discussed based on the subsequent growth process: the VLS catalyticgrowth of the ZnO nanowire and subsequent epitaxial SnO growth on the sidewall of the pre-grown ZnO nanowire.	n-zno	41-46	strawberry notch homolog 1	Homo sapiens	188-191
32639143-4	2020	A possible growth mechanism of the p-SnO/n-ZnO biaxial nanowires was discussed based on the subsequent growth process: the VLS catalyticgrowth of the ZnO nanowire and subsequent epitaxial SnO growth on the sidewall of the pre-grown ZnO nanowire.	Zinc Oxide	43-46	strawberry notch homolog 1	Homo sapiens	188-191
32639143-4	2020	A possible growth mechanism of the p-SnO/n-ZnO biaxial nanowires was discussed based on the subsequent growth process: the VLS catalyticgrowth of the ZnO nanowire and subsequent epitaxial SnO growth on the sidewall of the pre-grown ZnO nanowire.	Zinc Oxide	150-153	strawberry notch homolog 1	Homo sapiens	37-40
32639143-5	2020	An epitaxial relationship, (001)SnO//(110)ZnO and [110]SnO//[002]ZnO, was observed in the biaxial p-SnO/n-ZnOheterostructured nanowires.	Zinc Oxide	42-45	strawberry notch homolog 1	Homo sapiens	32-35
32639143-5	2020	An epitaxial relationship, (001)SnO//(110)ZnO and [110]SnO//[002]ZnO, was observed in the biaxial p-SnO/n-ZnOheterostructured nanowires.	Zinc Oxide	42-45	strawberry notch homolog 1	Homo sapiens	55-58
32639143-5	2020	An epitaxial relationship, (001)SnO//(110)ZnO and [110]SnO//[002]ZnO, was observed in the biaxial p-SnO/n-ZnOheterostructured nanowires.	Zinc Oxide	42-45	strawberry notch homolog 1	Homo sapiens	55-58
32639143-5	2020	An epitaxial relationship, (001)SnO//(110)ZnO and [110]SnO//[002]ZnO, was observed in the biaxial p-SnO/n-ZnOheterostructured nanowires.	Zinc Oxide	65-68	strawberry notch homolog 1	Homo sapiens	32-35
32639143-5	2020	An epitaxial relationship, (001)SnO//(110)ZnO and [110]SnO//[002]ZnO, was observed in the biaxial p-SnO/n-ZnOheterostructured nanowires.	Zinc Oxide	65-68	strawberry notch homolog 1	Homo sapiens	55-58
32639143-5	2020	An epitaxial relationship, (001)SnO//(110)ZnO and [110]SnO//[002]ZnO, was observed in the biaxial p-SnO/n-ZnOheterostructured nanowires.	Zinc Oxide	65-68	strawberry notch homolog 1	Homo sapiens	55-58
32639143-8	2020	The limit of detection of NO2 for the p-SnO/n-ZnO sensor is 50 ppb.	Nitrogen Dioxide	26-29	strawberry notch homolog 1	Homo sapiens	40-43
32496040-0	2020	Instant Post-Synthesis Aqueous Dispersion of Sb-doped SnO2 Nanocrystals: the Synergy between Small-Molecule Amine and Sb Dopant Ratio.	sb-doped	45-53	strawberry notch homolog 1	Homo sapiens	54-57
32109696-2	2020	Ti/CNT/SnO2-Sb-Er with an ultra-high oxygen evolution potential (2.15 V) and enhanced electrocatalytic surface area was adopted as anode.	Oxygen	37-43	strawberry notch homolog 1	Homo sapiens	7-10
32523126-7	2020	A dissolution-recrystallization process was taken into account as the mechanism for SnO particles formation, in which hydroxylated complexes, Sn2(OH)6-2, then condense to form the oxide.	Oxides	180-185	strawberry notch homolog 1	Homo sapiens	84-87
32571043-2	2020	In this study, we have carefully examined the temperature dependence on the bandgap of simple metal oxides, which are well-known photocatalysts, i.e., TiO2, CeO2, Nb2O5, SnO2 Ta2O5, WO3, ZnO, and ZrO2, using operando UV-visible spectroscopy under controlled temperature (from room temperature to 500  C).	metal oxides	94-106	strawberry notch homolog 1	Homo sapiens	170-173
32464501-4	2020	NO affects cellular signalling through protein S-nitrosylation, the NO-mediated posttranslational modification of cysteine thiols (SNO).	cysteine thiols	114-129	strawberry notch homolog 1	Homo sapiens	131-134
32599573-7	2020	The structural and chemical characterizations showed that the ethanol gas sensing performance of Pd:SnO2/PANI/P3HB nanocomposite fibers mainly attributed to the p-n heterojunction, fibers geometry, one dimensional structure of SnO2and the presence of Pd catalyst.	Ethanol	62-69	strawberry notch homolog 1	Homo sapiens	100-103
32599573-7	2020	The structural and chemical characterizations showed that the ethanol gas sensing performance of Pd:SnO2/PANI/P3HB nanocomposite fibers mainly attributed to the p-n heterojunction, fibers geometry, one dimensional structure of SnO2and the presence of Pd catalyst.	Palladium	97-99	strawberry notch homolog 1	Homo sapiens	100-103
32599573-7	2020	The structural and chemical characterizations showed that the ethanol gas sensing performance of Pd:SnO2/PANI/P3HB nanocomposite fibers mainly attributed to the p-n heterojunction, fibers geometry, one dimensional structure of SnO2and the presence of Pd catalyst.	polyaniline	105-109	strawberry notch homolog 1	Homo sapiens	100-103
32599573-7	2020	The structural and chemical characterizations showed that the ethanol gas sensing performance of Pd:SnO2/PANI/P3HB nanocomposite fibers mainly attributed to the p-n heterojunction, fibers geometry, one dimensional structure of SnO2and the presence of Pd catalyst.	p3hb	110-114	strawberry notch homolog 1	Homo sapiens	100-103
32599573-7	2020	The structural and chemical characterizations showed that the ethanol gas sensing performance of Pd:SnO2/PANI/P3HB nanocomposite fibers mainly attributed to the p-n heterojunction, fibers geometry, one dimensional structure of SnO2and the presence of Pd catalyst.	Palladium	251-253	strawberry notch homolog 1	Homo sapiens	100-103
32571043-2	2020	In this study, we have carefully examined the temperature dependence on the bandgap of simple metal oxides, which are well-known photocatalysts, i.e., TiO2, CeO2, Nb2O5, SnO2 Ta2O5, WO3, ZnO, and ZrO2, using operando UV-visible spectroscopy under controlled temperature (from room temperature to 500  C).	ta2o5	175-180	strawberry notch homolog 1	Homo sapiens	170-173
32570834-0	2020	SnS2 and SnO2 Nanoparticles Obtained from Organotin(IV) Dithiocarbamate Complex and Their Photocatalytic Activities on Methylene Blue.	Dithiocarbamate	56-71	strawberry notch homolog 1	Homo sapiens	9-12
32570834-0	2020	SnS2 and SnO2 Nanoparticles Obtained from Organotin(IV) Dithiocarbamate Complex and Their Photocatalytic Activities on Methylene Blue.	Methylene Blue	119-133	strawberry notch homolog 1	Homo sapiens	9-12
32088454-5	2020	Particularly, the sensor base on the fabricated WO3@SnO2 nanosheets with 20-nm SnO2 shell layer demonstrated superior gas sensing performance with the highest response (1.55) and selectivity toward 15 ppm NH3 at 200  C. This remarkable enhancement of NH3 sensing ability could be ascribed to the formation of unique WO3-SnO2 core-shell heterojunction structure.	wo3	48-51	strawberry notch homolog 1	Homo sapiens	52-55
32582622-0	2020	Interface Design of SnO2@PANI Nanotube With Enhanced Sensing Performance for Ammonia Detection at Room Temperature.	Ammonia	77-84	strawberry notch homolog 1	Homo sapiens	20-23
32088454-5	2020	Particularly, the sensor base on the fabricated WO3@SnO2 nanosheets with 20-nm SnO2 shell layer demonstrated superior gas sensing performance with the highest response (1.55) and selectivity toward 15 ppm NH3 at 200  C. This remarkable enhancement of NH3 sensing ability could be ascribed to the formation of unique WO3-SnO2 core-shell heterojunction structure.	Tin(IV) oxide	79-83	strawberry notch homolog 1	Homo sapiens	52-55
32088454-5	2020	Particularly, the sensor base on the fabricated WO3@SnO2 nanosheets with 20-nm SnO2 shell layer demonstrated superior gas sensing performance with the highest response (1.55) and selectivity toward 15 ppm NH3 at 200  C. This remarkable enhancement of NH3 sensing ability could be ascribed to the formation of unique WO3-SnO2 core-shell heterojunction structure.	Ammonia	205-208	strawberry notch homolog 1	Homo sapiens	52-55
32088454-5	2020	Particularly, the sensor base on the fabricated WO3@SnO2 nanosheets with 20-nm SnO2 shell layer demonstrated superior gas sensing performance with the highest response (1.55) and selectivity toward 15 ppm NH3 at 200  C. This remarkable enhancement of NH3 sensing ability could be ascribed to the formation of unique WO3-SnO2 core-shell heterojunction structure.	Ammonia	251-254	strawberry notch homolog 1	Homo sapiens	52-55
32249864-0	2020	Electron injection effect in In2O3 and SnO2 nanocrystals modified by ruthenium heteroleptic complexes.	Ruthenium	69-78	strawberry notch homolog 1	Homo sapiens	39-42
31896160-5	2020	Until the present investigation, gaseous salts where SnO plays the role of an anion-forming oxide had been unknown.	Oxides	92-97	strawberry notch homolog 1	Homo sapiens	53-56
31896160-10	2020	RESULTS: Ba, BaO, Ba2 O2 , SnO and BaSnO2 were found to be the main species in the vapor over the BaO-SnO2 mixture in the temperature range of 1680 - 1920 K. The standard formation enthalpies of gaseous BaSnO2 and Ba2 O2 were determined on the basis of the equilibrium constants of the studied gas-phase reactions.	Barium	98-101	strawberry notch homolog 1	Homo sapiens	27-30
32186359-2	2020	Herein, we report a novel 2D confined electrocatalyst composed of core-shell structured tin oxide nanoparticles (NPs) encapsulated into N-doped carbon (NC) supported on electrochemically exfoliated graphene (SnO2 NC@EEG) prepared by in-situ carbonization of 2-methylimidazole/SnO2 complex@polyvinyl pyrrolidone (PVP)-modified EEG precursor.	stannic oxide	88-97	strawberry notch homolog 1	Homo sapiens	208-211
31898457-8	2020	Most importantly, the sensing kinetics is remarkably fast; both the response to the analyte gas and the signal decay after gas exposure occur within few seconds, faster than in standard SnO2-based CO sensors.	Carbon Monoxide	197-199	strawberry notch homolog 1	Homo sapiens	186-189
32108432-2	2020	Herein, the construction of a multifunctional biomaterial system is reported by the integration of 2D Nb2 C MXene wrapped with S-nitrosothiol (R SNO)-grafted mesoporous silica with 3D-printing bioactive glass (BG) scaffolds (MBS).	S-Nitrosothiols	127-141	strawberry notch homolog 1	Homo sapiens	145-148
32108432-2	2020	Herein, the construction of a multifunctional biomaterial system is reported by the integration of 2D Nb2 C MXene wrapped with S-nitrosothiol (R SNO)-grafted mesoporous silica with 3D-printing bioactive glass (BG) scaffolds (MBS).	Silicon Dioxide	169-175	strawberry notch homolog 1	Homo sapiens	145-148
31944516-3	2020	Herein, we demonstrate that the SnO x shell in Sn 2.7 Cu catalyst with hierarchical Sn-Cu core can be in situ reconstructed under cathodic potentials of CO 2 RR.	Copper	54-56	strawberry notch homolog 1	Homo sapiens	32-35
31944516-3	2020	Herein, we demonstrate that the SnO x shell in Sn 2.7 Cu catalyst with hierarchical Sn-Cu core can be in situ reconstructed under cathodic potentials of CO 2 RR.	Tin	84-89	strawberry notch homolog 1	Homo sapiens	32-35
31944516-3	2020	Herein, we demonstrate that the SnO x shell in Sn 2.7 Cu catalyst with hierarchical Sn-Cu core can be in situ reconstructed under cathodic potentials of CO 2 RR.	Carbon Dioxide	153-157	strawberry notch homolog 1	Homo sapiens	32-35
31944516-5	2020	Density functional theory calculations indicate that the in situ reconstructed Sn/SnO x interface facilitates formic acid production by optimizing the binding of the reaction intermediate HCOO* while promotes Faradaic efficiency of C 1 products by suppressing the competitive hydrogen evolution reaction, resulting in high Faradaic efficiency, current density and stability of CO 2 RR at low overpotentials.	Tin	79-81	strawberry notch homolog 1	Homo sapiens	82-85
31944516-5	2020	Density functional theory calculations indicate that the in situ reconstructed Sn/SnO x interface facilitates formic acid production by optimizing the binding of the reaction intermediate HCOO* while promotes Faradaic efficiency of C 1 products by suppressing the competitive hydrogen evolution reaction, resulting in high Faradaic efficiency, current density and stability of CO 2 RR at low overpotentials.	formic acid	110-121	strawberry notch homolog 1	Homo sapiens	82-85
31944516-5	2020	Density functional theory calculations indicate that the in situ reconstructed Sn/SnO x interface facilitates formic acid production by optimizing the binding of the reaction intermediate HCOO* while promotes Faradaic efficiency of C 1 products by suppressing the competitive hydrogen evolution reaction, resulting in high Faradaic efficiency, current density and stability of CO 2 RR at low overpotentials.	Hydrogen	276-284	strawberry notch homolog 1	Homo sapiens	82-85
31944516-5	2020	Density functional theory calculations indicate that the in situ reconstructed Sn/SnO x interface facilitates formic acid production by optimizing the binding of the reaction intermediate HCOO* while promotes Faradaic efficiency of C 1 products by suppressing the competitive hydrogen evolution reaction, resulting in high Faradaic efficiency, current density and stability of CO 2 RR at low overpotentials.	Carbon Dioxide	377-381	strawberry notch homolog 1	Homo sapiens	82-85
31671223-1	2020	We report the first oxynitride of tin, Sn2N2O (SNO), exhibiting a Rh2S3-type crystal structure with space group Pbcn.	oxynitride	20-30	strawberry notch homolog 1	Homo sapiens	39-45
31492349-0	2020	Preparation of SnO Nanoshells with Enhanced Lithium-Storage Properties.	Lithium	44-51	strawberry notch homolog 1	Homo sapiens	15-18
32171198-1	2020	The bifunctional mechanism for the oxygen evolution reaction (OER) involving two distinct reaction sites is studied through the computational hydrogen electrode method for a set of catalyst materials including rutile TiO2(110), anatase TiO2(101), SnO2(110), RuO2(110), IrO2(110), Ni2P(0001), and BiVO4(001).	Oxygen	35-41	strawberry notch homolog 1	Homo sapiens	247-250
31671223-1	2020	We report the first oxynitride of tin, Sn2N2O (SNO), exhibiting a Rh2S3-type crystal structure with space group Pbcn.	oxynitride	20-30	strawberry notch homolog 1	Homo sapiens	47-50
31671223-1	2020	We report the first oxynitride of tin, Sn2N2O (SNO), exhibiting a Rh2S3-type crystal structure with space group Pbcn.	Tin	34-37	strawberry notch homolog 1	Homo sapiens	39-45
31671223-1	2020	We report the first oxynitride of tin, Sn2N2O (SNO), exhibiting a Rh2S3-type crystal structure with space group Pbcn.	Tin	34-37	strawberry notch homolog 1	Homo sapiens	47-50
31671223-1	2020	We report the first oxynitride of tin, Sn2N2O (SNO), exhibiting a Rh2S3-type crystal structure with space group Pbcn.	Rhodium	66-71	strawberry notch homolog 1	Homo sapiens	39-45
31671223-1	2020	We report the first oxynitride of tin, Sn2N2O (SNO), exhibiting a Rh2S3-type crystal structure with space group Pbcn.	Rhodium	66-71	strawberry notch homolog 1	Homo sapiens	47-50
31631883-0	2020	X-ray spectroscopy study on the electronic structure of Sn-added p-type SnO films.	Tin	56-58	strawberry notch homolog 1	Homo sapiens	72-75
32035445-0	2020	Surface chemistry of 2-propanol and O2 mixtures on SnO2(110) studied with ambient-pressure x-ray photoelectron spectroscopy.	2-Propanol	21-31	strawberry notch homolog 1	Homo sapiens	51-54
32035445-0	2020	Surface chemistry of 2-propanol and O2 mixtures on SnO2(110) studied with ambient-pressure x-ray photoelectron spectroscopy.	Superoxides	36-38	strawberry notch homolog 1	Homo sapiens	51-54
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	63-65	strawberry notch homolog 1	Homo sapiens	38-41
33105115-2	2020	Among oxide materials, the layered tin oxides (SnO) attract raising attention in the electronic and optoelectronic field owing to their lone pair electrons.	Oxides	6-11	strawberry notch homolog 1	Homo sapiens	47-50
33105115-2	2020	Among oxide materials, the layered tin oxides (SnO) attract raising attention in the electronic and optoelectronic field owing to their lone pair electrons.	stannic oxide	35-45	strawberry notch homolog 1	Homo sapiens	47-50
33105115-7	2020	Our results demonstrate that layered SnO will be the potential n-type two-dimensional oxide thermoelectric material.	Oxides	86-91	strawberry notch homolog 1	Homo sapiens	37-40
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	63-65	strawberry notch homolog 1	Homo sapiens	72-75
31631883-1	2020	The electronic structure of the Sn-added p-type SnO thin film was examined using x-ray absorption spectroscopy (XAS).	Tin	32-34	strawberry notch homolog 1	Homo sapiens	48-51
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	63-65	strawberry notch homolog 1	Homo sapiens	72-75
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	63-65	strawberry notch homolog 1	Homo sapiens	72-75
31631883-2	2020	Sn was intentionally added to a pristine SnO film, and the film was annealed to form p-type SnO.	Tin	0-2	strawberry notch homolog 1	Homo sapiens	41-44
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	231-235	strawberry notch homolog 1	Homo sapiens	72-75
31631883-2	2020	Sn was intentionally added to a pristine SnO film, and the film was annealed to form p-type SnO.	Tin	0-2	strawberry notch homolog 1	Homo sapiens	92-95
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	231-235	strawberry notch homolog 1	Homo sapiens	72-75
31631883-3	2020	Sn L1- and L3-edge XAS was used to examine the oxidation states of the Sn-added p-type SnO.	Tin	0-2	strawberry notch homolog 1	Homo sapiens	87-90
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	231-235	strawberry notch homolog 1	Homo sapiens	72-75
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	63-65	strawberry notch homolog 1	Homo sapiens	38-41
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	63-65	strawberry notch homolog 1	Homo sapiens	72-75
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	63-65	strawberry notch homolog 1	Homo sapiens	72-75
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	63-65	strawberry notch homolog 1	Homo sapiens	72-75
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	231-235	strawberry notch homolog 1	Homo sapiens	72-75
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	231-235	strawberry notch homolog 1	Homo sapiens	72-75
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	231-235	strawberry notch homolog 1	Homo sapiens	72-75
31631883-7	2020	The large bandgap after annealing suggests that the metallic Sn was no longer in existence and manifested the functionality of the annealed Sn  +  SnO as a p-type semiconductor.	Tin	61-63	strawberry notch homolog 1	Homo sapiens	147-150
31631883-3	2020	Sn L1- and L3-edge XAS was used to examine the oxidation states of the Sn-added p-type SnO.	Tin	71-73	strawberry notch homolog 1	Homo sapiens	87-90
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	129-133	strawberry notch homolog 1	Homo sapiens	72-75
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	129-133	strawberry notch homolog 1	Homo sapiens	72-75
31631883-4	2020	Compared to the case of the reference SnO, the spectrum of the Sn-added SnO (after annealing) partly contained the lineshape for SnO2, suggesting that the oxidation of Sn  +  SnO was progressed such that the film became preferably SnO2  +  SnO rather than Sn  +  SnO2.	Tin	129-133	strawberry notch homolog 1	Homo sapiens	72-75
31693344-3	2019	We focus on the properties of two "crosstalk" intermediates, SNO- (thionitrite) and SSNO- (perthionitrite, nitrosodisulfide) based in the largely controversial status on their identity and chemistry in aqueous/nonaqueous media, en route to the final products N2O, NO2-, NH2OH/NH3, and S8.	N-acetyl-1-amino-2-methylpropyl-2-thionitrite	67-78	strawberry notch homolog 1	Homo sapiens	61-64
31693344-3	2019	We focus on the properties of two "crosstalk" intermediates, SNO- (thionitrite) and SSNO- (perthionitrite, nitrosodisulfide) based in the largely controversial status on their identity and chemistry in aqueous/nonaqueous media, en route to the final products N2O, NO2-, NH2OH/NH3, and S8.	Superoxides	259-262	strawberry notch homolog 1	Homo sapiens	61-64
31693344-3	2019	We focus on the properties of two "crosstalk" intermediates, SNO- (thionitrite) and SSNO- (perthionitrite, nitrosodisulfide) based in the largely controversial status on their identity and chemistry in aqueous/nonaqueous media, en route to the final products N2O, NO2-, NH2OH/NH3, and S8.	hydroxide ion	264-275	strawberry notch homolog 1	Homo sapiens	61-64
31693344-3	2019	We focus on the properties of two "crosstalk" intermediates, SNO- (thionitrite) and SSNO- (perthionitrite, nitrosodisulfide) based in the largely controversial status on their identity and chemistry in aqueous/nonaqueous media, en route to the final products N2O, NO2-, NH2OH/NH3, and S8.	Ammonia	276-279	strawberry notch homolog 1	Homo sapiens	61-64
31693344-4	2019	Thionitrous acid, generated either in the direct reaction of NO + H2S or through the transnitrosation of RSNO"s (nitrosothiols) with H2S at pH 7.4, is best described as a mixture of rapidly interconverting isomers, {(H)SNO}.	S-nitroso-2-mercaptoethylamine	0-16	strawberry notch homolog 1	Homo sapiens	106-109
31693344-4	2019	Thionitrous acid, generated either in the direct reaction of NO + H2S or through the transnitrosation of RSNO"s (nitrosothiols) with H2S at pH 7.4, is best described as a mixture of rapidly interconverting isomers, {(H)SNO}.	S-Nitrosothiols	113-126	strawberry notch homolog 1	Homo sapiens	106-109
31693344-4	2019	Thionitrous acid, generated either in the direct reaction of NO + H2S or through the transnitrosation of RSNO"s (nitrosothiols) with H2S at pH 7.4, is best described as a mixture of rapidly interconverting isomers, {(H)SNO}.	hydrogen sulfite	133-136	strawberry notch homolog 1	Homo sapiens	106-109
31693344-7	2019	The latter mixture can also react with HS-, giving HNO and HS2- (hydrogen disulfide), a S0(sulfane)-transfer reagent toward {(H)SNO}, leading to SSNO-, a moderately stable species that slowly decomposes in aqueous sulfide-containing solutions in the minute-hour time scale, depending on [O2].	nitroxyl	51-54	strawberry notch homolog 1	Homo sapiens	128-131
31693344-7	2019	The latter mixture can also react with HS-, giving HNO and HS2- (hydrogen disulfide), a S0(sulfane)-transfer reagent toward {(H)SNO}, leading to SSNO-, a moderately stable species that slowly decomposes in aqueous sulfide-containing solutions in the minute-hour time scale, depending on [O2].	Hydrogen	65-83	strawberry notch homolog 1	Homo sapiens	128-131
31693344-7	2019	The latter mixture can also react with HS-, giving HNO and HS2- (hydrogen disulfide), a S0(sulfane)-transfer reagent toward {(H)SNO}, leading to SSNO-, a moderately stable species that slowly decomposes in aqueous sulfide-containing solutions in the minute-hour time scale, depending on [O2].	E-(4-(4-bromostyryl)phenyl)(methyl)sulfane	88-99	strawberry notch homolog 1	Homo sapiens	128-131
31693344-7	2019	The latter mixture can also react with HS-, giving HNO and HS2- (hydrogen disulfide), a S0(sulfane)-transfer reagent toward {(H)SNO}, leading to SSNO-, a moderately stable species that slowly decomposes in aqueous sulfide-containing solutions in the minute-hour time scale, depending on [O2].	ssno	145-149	strawberry notch homolog 1	Homo sapiens	128-131
31757045-3	2019	This work demonstrated a vertically stacked three-dimensional complementary inverter composed of a p-channel tin monoxide (SnO) TFT and an n-channel indium-gallium-zinc oxide (IGZO) TFT.	nickel monoxide	113-121	strawberry notch homolog 1	Homo sapiens	123-126
31693344-7	2019	The latter mixture can also react with HS-, giving HNO and HS2- (hydrogen disulfide), a S0(sulfane)-transfer reagent toward {(H)SNO}, leading to SSNO-, a moderately stable species that slowly decomposes in aqueous sulfide-containing solutions in the minute-hour time scale, depending on [O2].	Sulfides	76-83	strawberry notch homolog 1	Homo sapiens	128-131
31757045-4	2019	A bottom-gate p-channel SnO TFT was formed on the top-gate n-channel IGZO TFT with a shared common gate electrode.	gallium oxide	69-73	strawberry notch homolog 1	Homo sapiens	24-27
31693344-7	2019	The latter mixture can also react with HS-, giving HNO and HS2- (hydrogen disulfide), a S0(sulfane)-transfer reagent toward {(H)SNO}, leading to SSNO-, a moderately stable species that slowly decomposes in aqueous sulfide-containing solutions in the minute-hour time scale, depending on [O2].	Superoxides	288-290	strawberry notch homolog 1	Homo sapiens	128-131
31824922-0	2019	Hollow WO3/SnO2 Hetero-Nanofibers: Controlled Synthesis and High Efficiency of Acetone Vapor Detection.	Acetone	79-86	strawberry notch homolog 1	Homo sapiens	11-14
31693344-8	2019	The previous characterization of HSNO/SNO- and SSNO- is critically discussed based on the available chemical and spectroscopic evidence (mass spectrometry, UV-vis, 15N NMR, Fourier transform infrared), together with computational studies including quantum mechanics/molecular mechanics molecular dynamics simulations that provide a structural and UV-vis description of the solvatochromic properties of cis-SSNO- acting as an electron donor in water, alcohols, and aprotic acceptor solvents.	Nitrogen	164-167	strawberry notch homolog 1	Homo sapiens	34-37
31824922-4	2019	Gas sensing tests display that the WO3/SnO2 (0.3 wt%) sensor not only exhibits the highest response (30.28) and excellent selectivity to acetone vapor at the lower detection temperature (170 C), 6 times higher than that of pure SnO2 (5.2), but still achieves a considerable response (4.7) when the acetone concentration is down to 100 ppb with the corresponding response/recovery times of 50/200 s, respectively.	Acetone	137-144	strawberry notch homolog 1	Homo sapiens	39-42
31824922-4	2019	Gas sensing tests display that the WO3/SnO2 (0.3 wt%) sensor not only exhibits the highest response (30.28) and excellent selectivity to acetone vapor at the lower detection temperature (170 C), 6 times higher than that of pure SnO2 (5.2), but still achieves a considerable response (4.7) when the acetone concentration is down to 100 ppb with the corresponding response/recovery times of 50/200 s, respectively.	Acetone	298-305	strawberry notch homolog 1	Homo sapiens	39-42
31693344-8	2019	The previous characterization of HSNO/SNO- and SSNO- is critically discussed based on the available chemical and spectroscopic evidence (mass spectrometry, UV-vis, 15N NMR, Fourier transform infrared), together with computational studies including quantum mechanics/molecular mechanics molecular dynamics simulations that provide a structural and UV-vis description of the solvatochromic properties of cis-SSNO- acting as an electron donor in water, alcohols, and aprotic acceptor solvents.	NSC 153174	402-410	strawberry notch homolog 1	Homo sapiens	34-37
31693344-8	2019	The previous characterization of HSNO/SNO- and SSNO- is critically discussed based on the available chemical and spectroscopic evidence (mass spectrometry, UV-vis, 15N NMR, Fourier transform infrared), together with computational studies including quantum mechanics/molecular mechanics molecular dynamics simulations that provide a structural and UV-vis description of the solvatochromic properties of cis-SSNO- acting as an electron donor in water, alcohols, and aprotic acceptor solvents.	Ethanol	450-458	strawberry notch homolog 1	Homo sapiens	34-37
31693344-10	2019	The analysis extends to the coordination abilities of {(H)SNO}, SNO-, and SSNO- into heme and nonheme iron centers, providing a basis for best unraveling their putative specific signaling roles.	Heme	85-89	strawberry notch homolog 1	Homo sapiens	58-61
31693344-10	2019	The analysis extends to the coordination abilities of {(H)SNO}, SNO-, and SSNO- into heme and nonheme iron centers, providing a basis for best unraveling their putative specific signaling roles.	Iron	102-106	strawberry notch homolog 1	Homo sapiens	58-61
31465940-4	2019	The PFC nanoliposomes (FI@Lip) and biocompatible NO donor S-nitrosated human serum albumin (HSA-SNO) were combined to synergistically combat the obstacle of tumor micro-environment, reducing GSH concentration and increasing singlet oxygen (1O2) generation.	Altretamine	92-95	strawberry notch homolog 1	Homo sapiens	96-99
31956425-0	2020	Wood-Derived Carbon Fibers Embedded with SnO x Nanoparticles as Anode Material for Lithium-Ion Batteries.	Carbon	13-19	strawberry notch homolog 1	Homo sapiens	41-44
31956425-0	2020	Wood-Derived Carbon Fibers Embedded with SnO x Nanoparticles as Anode Material for Lithium-Ion Batteries.	Lithium	83-90	strawberry notch homolog 1	Homo sapiens	41-44
31956425-1	2020	Carbon-SnO x composites are obtained by impregnating acetylacetone-treated, delignified wood fibers with tin precursor and successively carbonizing at 1000  C in 95% argon and 5% oxygen.	Carbon	0-6	strawberry notch homolog 1	Homo sapiens	7-10
31956425-1	2020	Carbon-SnO x composites are obtained by impregnating acetylacetone-treated, delignified wood fibers with tin precursor and successively carbonizing at 1000  C in 95% argon and 5% oxygen.	acetylacetone	53-66	strawberry notch homolog 1	Homo sapiens	7-10
31956425-1	2020	Carbon-SnO x composites are obtained by impregnating acetylacetone-treated, delignified wood fibers with tin precursor and successively carbonizing at 1000  C in 95% argon and 5% oxygen.	Tin	48-51	strawberry notch homolog 1	Homo sapiens	7-10
31956425-1	2020	Carbon-SnO x composites are obtained by impregnating acetylacetone-treated, delignified wood fibers with tin precursor and successively carbonizing at 1000  C in 95% argon and 5% oxygen.	Oxygen	179-185	strawberry notch homolog 1	Homo sapiens	7-10
31956425-5	2020	The resultant carbon-SnO x material with 16 wt% SnO x shows excellent electrochemical performance of rate capability from 0.1 to 10 A g-1 and cycling stability for 1000 cycles with Li-ion storage capacity of 280 mAh g-1 at a current density of 10 A g-1.	Carbon	14-20	strawberry notch homolog 1	Homo sapiens	21-24
31956425-5	2020	The resultant carbon-SnO x material with 16 wt% SnO x shows excellent electrochemical performance of rate capability from 0.1 to 10 A g-1 and cycling stability for 1000 cycles with Li-ion storage capacity of 280 mAh g-1 at a current density of 10 A g-1.	Carbon	14-20	strawberry notch homolog 1	Homo sapiens	48-51
31956425-6	2020	The remarkable electrochemical performance of wood-derived carbon-SnO x composite is attributed to the reproduction of structural featured wood fibers to nanoscale in carbon-SnO x composite and controlled passivation of tin nanoparticles to yield SnO x nanoparticles.	Carbon	59-65	strawberry notch homolog 1	Homo sapiens	66-69
31956425-6	2020	The remarkable electrochemical performance of wood-derived carbon-SnO x composite is attributed to the reproduction of structural featured wood fibers to nanoscale in carbon-SnO x composite and controlled passivation of tin nanoparticles to yield SnO x nanoparticles.	Carbon	59-65	strawberry notch homolog 1	Homo sapiens	174-177
31956425-6	2020	The remarkable electrochemical performance of wood-derived carbon-SnO x composite is attributed to the reproduction of structural featured wood fibers to nanoscale in carbon-SnO x composite and controlled passivation of tin nanoparticles to yield SnO x nanoparticles.	Carbon	59-65	strawberry notch homolog 1	Homo sapiens	174-177
31956425-6	2020	The remarkable electrochemical performance of wood-derived carbon-SnO x composite is attributed to the reproduction of structural featured wood fibers to nanoscale in carbon-SnO x composite and controlled passivation of tin nanoparticles to yield SnO x nanoparticles.	Carbon	167-173	strawberry notch homolog 1	Homo sapiens	66-69
31956425-6	2020	The remarkable electrochemical performance of wood-derived carbon-SnO x composite is attributed to the reproduction of structural featured wood fibers to nanoscale in carbon-SnO x composite and controlled passivation of tin nanoparticles to yield SnO x nanoparticles.	Carbon	167-173	strawberry notch homolog 1	Homo sapiens	174-177
31956425-6	2020	The remarkable electrochemical performance of wood-derived carbon-SnO x composite is attributed to the reproduction of structural featured wood fibers to nanoscale in carbon-SnO x composite and controlled passivation of tin nanoparticles to yield SnO x nanoparticles.	Carbon	167-173	strawberry notch homolog 1	Homo sapiens	174-177
31956425-6	2020	The remarkable electrochemical performance of wood-derived carbon-SnO x composite is attributed to the reproduction of structural featured wood fibers to nanoscale in carbon-SnO x composite and controlled passivation of tin nanoparticles to yield SnO x nanoparticles.	Tin	220-223	strawberry notch homolog 1	Homo sapiens	66-69
31465940-6	2019	In addition, with co-delivery of HSA-SNO, it can effectively promote GSH depletion to recover 1O2 level and release NO concurrently to inhibit mitochondrial respiration.	Altretamine	33-36	strawberry notch homolog 1	Homo sapiens	37-40
31465940-6	2019	In addition, with co-delivery of HSA-SNO, it can effectively promote GSH depletion to recover 1O2 level and release NO concurrently to inhibit mitochondrial respiration.	Glutathione	69-72	strawberry notch homolog 1	Homo sapiens	37-40
31465940-6	2019	In addition, with co-delivery of HSA-SNO, it can effectively promote GSH depletion to recover 1O2 level and release NO concurrently to inhibit mitochondrial respiration.	CHEBI:63768	94-97	strawberry notch homolog 1	Homo sapiens	37-40
31465940-7	2019	This combination strategy of FI@Lip and HSA-SNO obviously relieved intracellular hypoxia and decreased GSH to increase more toxic 1O2 generation for PDT enhancement.	Altretamine	40-43	strawberry notch homolog 1	Homo sapiens	44-47
31465940-7	2019	This combination strategy of FI@Lip and HSA-SNO obviously relieved intracellular hypoxia and decreased GSH to increase more toxic 1O2 generation for PDT enhancement.	Glutathione	103-106	strawberry notch homolog 1	Homo sapiens	44-47
31465940-7	2019	This combination strategy of FI@Lip and HSA-SNO obviously relieved intracellular hypoxia and decreased GSH to increase more toxic 1O2 generation for PDT enhancement.	CHEBI:63768	130-133	strawberry notch homolog 1	Homo sapiens	44-47
31323652-1	2019	Here, the ability of using p-type tin oxide (SnO x ) thin films as a thermal sensor has been investigated.	stannic oxide	34-43	strawberry notch homolog 1	Homo sapiens	45-48
31407886-1	2019	Improving the reversibility of conversion reaction is a promising way to enhance the lithium-ion storage capability of SnO2-based anodes.	Lithium	85-92	strawberry notch homolog 1	Homo sapiens	119-122
31577123-2	2019	As the Se loading increased, the SnSeO film structures were transformed from tetragonal SnO to orthorhombic SnSe, which was accompanied by an increase in the amorphous phase portion and smooth morphologies.	Selenium	7-9	strawberry notch homolog 1	Homo sapiens	88-91
31577123-2	2019	As the Se loading increased, the SnSeO film structures were transformed from tetragonal SnO to orthorhombic SnSe, which was accompanied by an increase in the amorphous phase portion and smooth morphologies.	Tin	33-38	strawberry notch homolog 1	Homo sapiens	88-91
31577123-2	2019	As the Se loading increased, the SnSeO film structures were transformed from tetragonal SnO to orthorhombic SnSe, which was accompanied by an increase in the amorphous phase portion and smooth morphologies.	Tin	33-37	strawberry notch homolog 1	Homo sapiens	88-91
31637538-2	2019	SOR undergoes CYP-mediated biotransformation to a pharmacologically active N-oxide metabolite (SNO) that has been shown to accumulate to varying extents in individuals.	sorafenib	0-3	strawberry notch homolog 1	Homo sapiens	95-98
31637538-2	2019	SOR undergoes CYP-mediated biotransformation to a pharmacologically active N-oxide metabolite (SNO) that has been shown to accumulate to varying extents in individuals.	1A-4N oxide	75-82	strawberry notch homolog 1	Homo sapiens	95-98
31637538-4	2019	Recent evidence has suggested that SNO is more effective than SOR as an inhibitor of CYP3A4-mediated midazolam 1"-hydroxylation.	Midazolam	101-110	strawberry notch homolog 1	Homo sapiens	35-38
31637538-7	2019	The inhibition kinetics of CYP2D6-mediated dextromethorphan O-demethylation were analyzed in human hepatic microsomes, with SNO found to be ~ 19-fold more active than SOR (Kis 1.8 +- 0.3 muM and 34 +- 11 muM, respectively).	Dextromethorphan	43-61	strawberry notch homolog 1	Homo sapiens	124-127
31637538-10	2019	However, a larger number of H-bonding interactions was noted between the N-oxide moiety of SNO and active site residues that account for its greater inhibition potency.	1A-4N oxide	73-80	strawberry notch homolog 1	Homo sapiens	91-94
31637538-11	2019	These findings suggest that SNO has the potential to contribute to pharmacokinetic interactions involving SOR, perhaps in those individuals in whom SNO accumulates.	sorafenib	106-109	strawberry notch homolog 1	Homo sapiens	28-31
31637538-11	2019	These findings suggest that SNO has the potential to contribute to pharmacokinetic interactions involving SOR, perhaps in those individuals in whom SNO accumulates.	sorafenib	106-109	strawberry notch homolog 1	Homo sapiens	148-151
31653835-4	2019	We have established a nanoporous Sb-doped SnO[Formula: see text] electrode as supporting electrode for chemisorbed electrochromic tetraphenylbenzidine molecules due to its good conductivity in the redox potential range of the molecule.	Antimony	33-35	strawberry notch homolog 1	Homo sapiens	42-45
31653835-4	2019	We have established a nanoporous Sb-doped SnO[Formula: see text] electrode as supporting electrode for chemisorbed electrochromic tetraphenylbenzidine molecules due to its good conductivity in the redox potential range of the molecule.	tetraphenylbenzidine	130-150	strawberry notch homolog 1	Homo sapiens	42-45
31407886-9	2019	This work demonstrates the promising additive of ferrocene in enhancing the reversible capacity of SnO2-based anodes for lithium-ion batteries.	ferrocene	49-58	strawberry notch homolog 1	Homo sapiens	99-102
31407886-9	2019	This work demonstrates the promising additive of ferrocene in enhancing the reversible capacity of SnO2-based anodes for lithium-ion batteries.	Lithium	121-128	strawberry notch homolog 1	Homo sapiens	99-102
31184144-0	2019	Dual-Site Cascade Oxygen Reduction Mechanism on SnO x/Pt-Cu-Ni for Promoting Reaction Kinetics.	Oxygen	18-24	strawberry notch homolog 1	Homo sapiens	48-51
30961716-1	2019	In this paper, the effect of channel annealing and oxygen flow rate in P-type tin-monoxide (SnO) thin film transistor (TFT) was investigated to reach the process compatibility with n-type oxide-based TFT.	Oxygen	51-57	strawberry notch homolog 1	Homo sapiens	92-95
30961716-1	2019	In this paper, the effect of channel annealing and oxygen flow rate in P-type tin-monoxide (SnO) thin film transistor (TFT) was investigated to reach the process compatibility with n-type oxide-based TFT.	tin-monoxide	78-90	strawberry notch homolog 1	Homo sapiens	92-95
30961716-1	2019	In this paper, the effect of channel annealing and oxygen flow rate in P-type tin-monoxide (SnO) thin film transistor (TFT) was investigated to reach the process compatibility with n-type oxide-based TFT.	Oxides	85-90	strawberry notch homolog 1	Homo sapiens	92-95
30961716-4	2019	Besides, the higher oxygen flow rate was also helpful for improving device mobility and driving current, but shows a slight increase in off-state leakage, which is unavoidable due to the increase of grain in SnO channel.	Oxygen	20-26	strawberry notch homolog 1	Homo sapiens	208-211
31184144-3	2019	Herein we report a new concept of utilizing dual active sites for the ORR and demonstrate its effectiveness by synthesizing a SnO x/Pt-Cu-Ni heterojunctioned catalyst.	Copper	135-137	strawberry notch homolog 1	Homo sapiens	126-129
30360189-0	2019	Electrochemical Performance of Sn/SnO/Ni3Sn Composite Anodes for Lithium-Ion Batteries.	Lithium	65-72	strawberry notch homolog 1	Homo sapiens	34-37
30869713-9	2019	When the in-plane biaxial strain turns from compressive to tensile, the magnetic anisotropy of CrN in monolayer SnO/CrN heterostructure increases, where the easy axis is perpendicular to the CrN layer.	corrin	95-98	strawberry notch homolog 1	Homo sapiens	112-115
30883663-5	2019	RESULTS: The ASCO/SNO Expert Panel determined that the recommendations from the CNS anticonvulsants and steroids guidelines, published January 9, 2019, are clear, thorough, and based upon the most relevant scientific evidence.	Steroids	104-112	strawberry notch homolog 1	Homo sapiens	18-21
30866429-4	2019	Tin monoxide (SnO), a member of IV-VI metal monoxides, has attracted much attention due to its low cost, environmental-friendly nature, and higher stability compared with other non-oxide ammonia sensing material like alkaline metal or polymer, which made this material an ideal alternative for ammonia sensor applications.	Tin(II) oxide	0-12	strawberry notch homolog 1	Homo sapiens	14-17
30866429-4	2019	Tin monoxide (SnO), a member of IV-VI metal monoxides, has attracted much attention due to its low cost, environmental-friendly nature, and higher stability compared with other non-oxide ammonia sensing material like alkaline metal or polymer, which made this material an ideal alternative for ammonia sensor applications.	metal monoxides	38-53	strawberry notch homolog 1	Homo sapiens	14-17
30866429-4	2019	Tin monoxide (SnO), a member of IV-VI metal monoxides, has attracted much attention due to its low cost, environmental-friendly nature, and higher stability compared with other non-oxide ammonia sensing material like alkaline metal or polymer, which made this material an ideal alternative for ammonia sensor applications.	Oxides	7-12	strawberry notch homolog 1	Homo sapiens	14-17
30866429-4	2019	Tin monoxide (SnO), a member of IV-VI metal monoxides, has attracted much attention due to its low cost, environmental-friendly nature, and higher stability compared with other non-oxide ammonia sensing material like alkaline metal or polymer, which made this material an ideal alternative for ammonia sensor applications.	Ammonia	187-194	strawberry notch homolog 1	Homo sapiens	14-17
30866429-4	2019	Tin monoxide (SnO), a member of IV-VI metal monoxides, has attracted much attention due to its low cost, environmental-friendly nature, and higher stability compared with other non-oxide ammonia sensing material like alkaline metal or polymer, which made this material an ideal alternative for ammonia sensor applications.	Metals	38-43	strawberry notch homolog 1	Homo sapiens	14-17
30866429-4	2019	Tin monoxide (SnO), a member of IV-VI metal monoxides, has attracted much attention due to its low cost, environmental-friendly nature, and higher stability compared with other non-oxide ammonia sensing material like alkaline metal or polymer, which made this material an ideal alternative for ammonia sensor applications.	Polymers	235-242	strawberry notch homolog 1	Homo sapiens	14-17
30866429-4	2019	Tin monoxide (SnO), a member of IV-VI metal monoxides, has attracted much attention due to its low cost, environmental-friendly nature, and higher stability compared with other non-oxide ammonia sensing material like alkaline metal or polymer, which made this material an ideal alternative for ammonia sensor applications.	Ammonia	294-301	strawberry notch homolog 1	Homo sapiens	14-17
30866429-5	2019	In this work, we fabricated high-sensitive ammonia sensors based on self-assembly SnO nanoshells via a solution method and annealing under 300  C for 1 h. The as fabricated sensors exhibited the response of 313%, 874%, 2757%, 3116%, and 3757% ( G/G) under ammonia concentration of 5 ppm, 20 ppm, 50 ppm, 100 ppm, and 200 ppm, respectively.	Ammonia	43-50	strawberry notch homolog 1	Homo sapiens	82-85
30866429-5	2019	In this work, we fabricated high-sensitive ammonia sensors based on self-assembly SnO nanoshells via a solution method and annealing under 300  C for 1 h. The as fabricated sensors exhibited the response of 313%, 874%, 2757%, 3116%, and 3757% ( G/G) under ammonia concentration of 5 ppm, 20 ppm, 50 ppm, 100 ppm, and 200 ppm, respectively.	Ammonia	256-263	strawberry notch homolog 1	Homo sapiens	82-85
30866429-7	2019	Further, the SnO nanoshells have higher oxygen vacancy densities compared with other metal oxide ammonia sensing materials, enabling it to have higher performance.	Oxygen	40-46	strawberry notch homolog 1	Homo sapiens	13-16
30866429-7	2019	Further, the SnO nanoshells have higher oxygen vacancy densities compared with other metal oxide ammonia sensing materials, enabling it to have higher performance.	metal oxide ammonia	85-104	strawberry notch homolog 1	Homo sapiens	13-16
31174373-0	2019	Enhancement of Acetone Gas-Sensing Responses of Tapered WO3 Nanorods through Sputtering Coating with a Thin SnO2 Coverage Layer.	Acetone	15-22	strawberry notch homolog 1	Homo sapiens	108-111
31174373-1	2019	WO3-SnO2 composite nanorods were synthesized by combining hydrothermal growth of tapered tungsten trioxide (WO3) nanorods and sputter deposition of thin SnO2 layers.	wo3	0-3	strawberry notch homolog 1	Homo sapiens	4-7
30712561-3	2019	Cu(I) is able to trigger cleavage of the SNO bond, which converts colored RSNOs to colorless products.	rsnos	74-79	strawberry notch homolog 1	Homo sapiens	41-44
30827111-0	2019	Enhanced Stability and CO/Formate Selectivity of Plasma-Treated SnO x/AgO x Catalysts during CO2 Electroreduction.	Carbon Monoxide	23-25	strawberry notch homolog 1	Homo sapiens	64-67
30827111-0	2019	Enhanced Stability and CO/Formate Selectivity of Plasma-Treated SnO x/AgO x Catalysts during CO2 Electroreduction.	formic acid	26-33	strawberry notch homolog 1	Homo sapiens	64-67
30827111-0	2019	Enhanced Stability and CO/Formate Selectivity of Plasma-Treated SnO x/AgO x Catalysts during CO2 Electroreduction.	N2,N6-bis(4-(2-aminoethoxy)quinolin-2-yl)-4-((4-fluorobenzyl)oxy)pyridine-2,6-dicarboxamide	93-96	strawberry notch homolog 1	Homo sapiens	64-67
30827111-3	2019	More stable and C1-product-selective SnO x/AgO x catalysts were obtained by electrodepositing Sn on O2-plasma-pretreated Ag surfaces.	Oxygen	100-102	strawberry notch homolog 1	Homo sapiens	37-40
30889924-3	2019	This study focusses on the identification of tin(II) oxide (tin monoxide, SnO) binding peptides, and their effect on the synthesis of crystalline SnO microstructures.	Tin(II) oxide	45-58	strawberry notch homolog 1	Homo sapiens	74-77
30889924-3	2019	This study focusses on the identification of tin(II) oxide (tin monoxide, SnO) binding peptides, and their effect on the synthesis of crystalline SnO microstructures.	Tin(II) oxide	45-58	strawberry notch homolog 1	Homo sapiens	146-149
30889924-3	2019	This study focusses on the identification of tin(II) oxide (tin monoxide, SnO) binding peptides, and their effect on the synthesis of crystalline SnO microstructures.	Tin(II) oxide	60-72	strawberry notch homolog 1	Homo sapiens	146-149
30538128-6	2019	Using mammalian cells, molecular modeling, substrate-capture assays, and mutagenic analyses, we identified a single conserved surface Lys (Lys-127) residue as well as active-site interactions of the SNO group that mediate recognition of SNO-CoA by SCoR.	Lysine	134-137	strawberry notch homolog 1	Homo sapiens	199-202
30538128-6	2019	Using mammalian cells, molecular modeling, substrate-capture assays, and mutagenic analyses, we identified a single conserved surface Lys (Lys-127) residue as well as active-site interactions of the SNO group that mediate recognition of SNO-CoA by SCoR.	Lysine	134-137	strawberry notch homolog 1	Homo sapiens	237-240
30538128-6	2019	Using mammalian cells, molecular modeling, substrate-capture assays, and mutagenic analyses, we identified a single conserved surface Lys (Lys-127) residue as well as active-site interactions of the SNO group that mediate recognition of SNO-CoA by SCoR.	Lysine	139-142	strawberry notch homolog 1	Homo sapiens	199-202
30538128-6	2019	Using mammalian cells, molecular modeling, substrate-capture assays, and mutagenic analyses, we identified a single conserved surface Lys (Lys-127) residue as well as active-site interactions of the SNO group that mediate recognition of SNO-CoA by SCoR.	Lysine	139-142	strawberry notch homolog 1	Homo sapiens	237-240
30360189-1	2019	We have synthesized a novel composite material Sn/SnO/Ni3Sn via galvanic replacement reaction between Sn and Ni2+ ions in triethylene glycol medium and at high temperature.	Tin	47-49	strawberry notch homolog 1	Homo sapiens	50-53
30360189-1	2019	We have synthesized a novel composite material Sn/SnO/Ni3Sn via galvanic replacement reaction between Sn and Ni2+ ions in triethylene glycol medium and at high temperature.	Nickel(2+)	109-113	strawberry notch homolog 1	Homo sapiens	50-53
30360189-1	2019	We have synthesized a novel composite material Sn/SnO/Ni3Sn via galvanic replacement reaction between Sn and Ni2+ ions in triethylene glycol medium and at high temperature.	triethylene glycol	122-140	strawberry notch homolog 1	Homo sapiens	50-53
30360189-4	2019	Among electrodes, the Sn/SnO/Ni3Sn-6h electrode demonstrated stable cycling and reversible capacity of 246 mAh g-1 even after 300 cycles owing to the advantages from the unique hybrid structure.	Tin	22-24	strawberry notch homolog 1	Homo sapiens	25-28
30360189-4	2019	Among electrodes, the Sn/SnO/Ni3Sn-6h electrode demonstrated stable cycling and reversible capacity of 246 mAh g-1 even after 300 cycles owing to the advantages from the unique hybrid structure.	ni3sn-6h	29-37	strawberry notch homolog 1	Homo sapiens	25-28
31012714-1	2019	We study the elastic energy landscape of two-dimensional tin oxide (SnO) monolayers and demonstrate a transition temperature of T_{c}=8.5+-1.8  K using ab initio molecular dynamics (MD) that is close to the value of the elastic energy barrier J derived from T=0  K density functional theory calculations.	stannic oxide	57-66	strawberry notch homolog 1	Homo sapiens	68-71
30624887-0	2019	Low-Temperature Plasma-Enhanced Atomic Layer Deposition of Tin(IV) Oxide from a Functionalized Alkyl Precursor: Fabrication and Evaluation of SnO2-Based Thin-Film Transistor Devices.	stannic oxide	59-72	strawberry notch homolog 1	Homo sapiens	142-145
31012714-1	2019	We study the elastic energy landscape of two-dimensional tin oxide (SnO) monolayers and demonstrate a transition temperature of T_{c}=8.5+-1.8  K using ab initio molecular dynamics (MD) that is close to the value of the elastic energy barrier J derived from T=0  K density functional theory calculations.	Technetium	128-132	strawberry notch homolog 1	Homo sapiens	68-71
30467756-3	2019	In phase II, the residual NH4+-N is further indirectly electrooxidized to nitrogen with modified Ti anode (Ti/SnO2-Sb-Pd).	nh4+-n	26-32	strawberry notch homolog 1	Homo sapiens	110-113
30627802-1	2019	The multi-kinase inhibitor sorafenib (SOR) is clinically important in the treatment of hepatocellular and renal cancers and undergoes CYP3A4-dependent oxidation in liver to the pharmacologically active N-oxide metabolite (SNO).	Sorafenib	27-36	strawberry notch homolog 1	Homo sapiens	222-225
30627802-9	2019	In the optimal docking pose, the N-oxide moiety of SNO was also found to interact directly with the heme moiety of CYP3A4.	n-oxide	33-40	strawberry notch homolog 1	Homo sapiens	51-54
30627802-9	2019	In the optimal docking pose, the N-oxide moiety of SNO was also found to interact directly with the heme moiety of CYP3A4.	Heme	100-104	strawberry notch homolog 1	Homo sapiens	51-54
30467756-3	2019	In phase II, the residual NH4+-N is further indirectly electrooxidized to nitrogen with modified Ti anode (Ti/SnO2-Sb-Pd).	Nitrogen	74-82	strawberry notch homolog 1	Homo sapiens	110-113
30334028-0	2018	In situ growth of heterostructured Sn/SnO nanospheres embedded in crumpled graphene as an anode material for lithium ion batteries.	Graphite	75-83	strawberry notch homolog 1	Homo sapiens	38-41
30334028-0	2018	In situ growth of heterostructured Sn/SnO nanospheres embedded in crumpled graphene as an anode material for lithium ion batteries.	Lithium	109-116	strawberry notch homolog 1	Homo sapiens	38-41
30334028-1	2018	The in situ growth of Sn/SnO heterostructured nanospheres embedded in crumpled graphene is based on a new strategy for the calcination of tin oleate coating on the crystal surface of sodium carbonate.	Tin	22-24	strawberry notch homolog 1	Homo sapiens	25-28
30334028-1	2018	The in situ growth of Sn/SnO heterostructured nanospheres embedded in crumpled graphene is based on a new strategy for the calcination of tin oleate coating on the crystal surface of sodium carbonate.	Graphite	79-87	strawberry notch homolog 1	Homo sapiens	25-28
30334028-1	2018	The in situ growth of Sn/SnO heterostructured nanospheres embedded in crumpled graphene is based on a new strategy for the calcination of tin oleate coating on the crystal surface of sodium carbonate.	9-Octadecenoic acid (9Z)-, tin salt	138-148	strawberry notch homolog 1	Homo sapiens	25-28
30334028-1	2018	The in situ growth of Sn/SnO heterostructured nanospheres embedded in crumpled graphene is based on a new strategy for the calcination of tin oleate coating on the crystal surface of sodium carbonate.	sodium carbonate	183-199	strawberry notch homolog 1	Homo sapiens	25-28
30334028-2	2018	Sn/SnO nanospheres and crumpled graphene are acquired simultaneously without external forces involved.	Tin	0-2	strawberry notch homolog 1	Homo sapiens	3-6
29894849-0	2018	The insight study of SnO pico size particles in an ethanol-water system followed by its biosensing application.	Ethanol	51-58	strawberry notch homolog 1	Homo sapiens	21-24
30281301-2	2018	The aim of this study was to compare nitrite with S-nitrosocysteine (Cys-SNO) and S-nitroso-N-acetylcysteine (NAC-SNO) with respect to N-NA formation, which was evaluated by determining the conversion of N-methylaniline to N-nitrosomethylaniline.	Nitrites	37-44	strawberry notch homolog 1	Homo sapiens	73-76
30281301-2	2018	The aim of this study was to compare nitrite with S-nitrosocysteine (Cys-SNO) and S-nitroso-N-acetylcysteine (NAC-SNO) with respect to N-NA formation, which was evaluated by determining the conversion of N-methylaniline to N-nitrosomethylaniline.	S-nitrosocysteine	50-67	strawberry notch homolog 1	Homo sapiens	73-76
30281301-2	2018	The aim of this study was to compare nitrite with S-nitrosocysteine (Cys-SNO) and S-nitroso-N-acetylcysteine (NAC-SNO) with respect to N-NA formation, which was evaluated by determining the conversion of N-methylaniline to N-nitrosomethylaniline.	S-nitroso-N-acetylcysteine	82-108	strawberry notch homolog 1	Homo sapiens	114-117
30281301-3	2018	Under neutral and acidic pH conditions, N-NA formation rate was nitrite &gt; Cys-SNO &gt; NAC-SNO.	n-na	40-44	strawberry notch homolog 1	Homo sapiens	81-84
30281301-3	2018	Under neutral and acidic pH conditions, N-NA formation rate was nitrite &gt; Cys-SNO &gt; NAC-SNO.	n-na	40-44	strawberry notch homolog 1	Homo sapiens	94-97
30281301-3	2018	Under neutral and acidic pH conditions, N-NA formation rate was nitrite &gt; Cys-SNO &gt; NAC-SNO.	Nitrites	64-71	strawberry notch homolog 1	Homo sapiens	81-84
30281301-3	2018	Under neutral and acidic pH conditions, N-NA formation rate was nitrite &gt; Cys-SNO &gt; NAC-SNO.	Nitrites	64-71	strawberry notch homolog 1	Homo sapiens	94-97
30281301-4	2018	In the presence of copper or nucleophiles, NAC-SNO generated much less N-NA than Cys-SNO.	Copper	19-25	strawberry notch homolog 1	Homo sapiens	47-50
30281301-4	2018	In the presence of copper or nucleophiles, NAC-SNO generated much less N-NA than Cys-SNO.	Copper	19-25	strawberry notch homolog 1	Homo sapiens	85-88
30281301-4	2018	In the presence of copper or nucleophiles, NAC-SNO generated much less N-NA than Cys-SNO.	n-na	71-75	strawberry notch homolog 1	Homo sapiens	47-50
30281301-5	2018	Nitrite and Cys-SNO produced higher amounts of N-NA in the presence of oxygen, whereas NAC-SNO was almost oxygen insensitive.	n-na	47-51	strawberry notch homolog 1	Homo sapiens	16-19
30281301-5	2018	Nitrite and Cys-SNO produced higher amounts of N-NA in the presence of oxygen, whereas NAC-SNO was almost oxygen insensitive.	Oxygen	71-77	strawberry notch homolog 1	Homo sapiens	16-19
30281301-6	2018	In meat in the stomach medium, NAC-SNO produced much lower amounts of N-NA than other additives.	n-na	70-74	strawberry notch homolog 1	Homo sapiens	35-38
30281301-7	2018	In heated meat, Cys-SNO and NAC-SNO generated the nitrosyl-hemochrome pink pigment, better than nitrite.	Cysteine	16-19	strawberry notch homolog 1	Homo sapiens	20-23
30281301-7	2018	In heated meat, Cys-SNO and NAC-SNO generated the nitrosyl-hemochrome pink pigment, better than nitrite.	Nitric Oxide	50-58	strawberry notch homolog 1	Homo sapiens	20-23
30281301-7	2018	In heated meat, Cys-SNO and NAC-SNO generated the nitrosyl-hemochrome pink pigment, better than nitrite.	Nitric Oxide	50-58	strawberry notch homolog 1	Homo sapiens	32-35
30281301-7	2018	In heated meat, Cys-SNO and NAC-SNO generated the nitrosyl-hemochrome pink pigment, better than nitrite.	hemochrome	59-69	strawberry notch homolog 1	Homo sapiens	20-23
30281301-7	2018	In heated meat, Cys-SNO and NAC-SNO generated the nitrosyl-hemochrome pink pigment, better than nitrite.	hemochrome	59-69	strawberry notch homolog 1	Homo sapiens	32-35
30281301-8	2018	In conclusion, NAC-SNO was much less reactive for N-NA formation than nitrite and Cys-SNO in conditions relevant to meat production and stomach digestion.	n-na	50-54	strawberry notch homolog 1	Homo sapiens	19-22
30351132-0	2018	Electrocatalytic Study of the Oxygen Reduction Reaction at Gold Nanoparticles in the Absence and Presence of Interactions with SnO x Supports.	Oxygen	30-36	strawberry notch homolog 1	Homo sapiens	127-130
30351132-1	2018	Here we report that density functional theory (DFT) can be used to accurately predict how Au nanoparticle (NP) catalysts cooperate with SnO x ( x = 1.9 or 2.0) supports to carry out the oxygen reduction reaction (ORR).	Oxygen	186-192	strawberry notch homolog 1	Homo sapiens	136-139
30092485-1	2018	A newly synthesized solid acid catalyst SO42-/SnO2-diatomite was prepared for synthesizing furfural from corncob in the presence of homogeneous Bronsted acid.	Sulfates	40-45	strawberry notch homolog 1	Homo sapiens	46-49
30092485-1	2018	A newly synthesized solid acid catalyst SO42-/SnO2-diatomite was prepared for synthesizing furfural from corncob in the presence of homogeneous Bronsted acid.	Furaldehyde	91-99	strawberry notch homolog 1	Homo sapiens	46-49
30092485-2	2018	The relationship between pKa of Bronsted acid and turnover frequency (TOF) of co-catalysis with Bronsted acid plus SO42-/SnO2-diatomite was explored on the conversion of corncob to furfural.	bronsted acid	32-45	strawberry notch homolog 1	Homo sapiens	121-124
30092485-2	2018	The relationship between pKa of Bronsted acid and turnover frequency (TOF) of co-catalysis with Bronsted acid plus SO42-/SnO2-diatomite was explored on the conversion of corncob to furfural.	Sulfates	115-120	strawberry notch homolog 1	Homo sapiens	121-124
30092485-2	2018	The relationship between pKa of Bronsted acid and turnover frequency (TOF) of co-catalysis with Bronsted acid plus SO42-/SnO2-diatomite was explored on the conversion of corncob to furfural.	corncob	170-177	strawberry notch homolog 1	Homo sapiens	121-124
30092485-2	2018	The relationship between pKa of Bronsted acid and turnover frequency (TOF) of co-catalysis with Bronsted acid plus SO42-/SnO2-diatomite was explored on the conversion of corncob to furfural.	Furaldehyde	181-189	strawberry notch homolog 1	Homo sapiens	121-124
30092485-3	2018	HCl (pKa = -7.0) (0.5 wt%) plus SO42-/SnO2-diatomite (3.6 wt%) gave the highest furfural yield (40.1%) with TOF value at 2.98 h-1 in the aqueous media.	Furaldehyde	80-88	strawberry notch homolog 1	Homo sapiens	38-41
29894849-0	2018	The insight study of SnO pico size particles in an ethanol-water system followed by its biosensing application.	Water	59-64	strawberry notch homolog 1	Homo sapiens	21-24
29894849-1	2018	Pico sized Stannous oxide particles (SnO PPs) were synthesized in an ethanol-water solvent system on the surface of nitrogen doped graphene oxide (GO).	Tin(II) oxide	11-25	strawberry notch homolog 1	Homo sapiens	37-40
29894849-1	2018	Pico sized Stannous oxide particles (SnO PPs) were synthesized in an ethanol-water solvent system on the surface of nitrogen doped graphene oxide (GO).	Nitrogen	116-124	strawberry notch homolog 1	Homo sapiens	37-40
29894849-1	2018	Pico sized Stannous oxide particles (SnO PPs) were synthesized in an ethanol-water solvent system on the surface of nitrogen doped graphene oxide (GO).	graphene oxide	131-145	strawberry notch homolog 1	Homo sapiens	37-40
29894849-1	2018	Pico sized Stannous oxide particles (SnO PPs) were synthesized in an ethanol-water solvent system on the surface of nitrogen doped graphene oxide (GO).	graphene oxide	147-149	strawberry notch homolog 1	Homo sapiens	37-40
29894849-4	2018	The change in the local chemical environment of GO via dual interactions provided a suitable atmosphere for the growth and dispersion of SnO PPs on GO-AMBA surface.	go-amba	148-155	strawberry notch homolog 1	Homo sapiens	137-140
29894849-5	2018	The possible mechanism for the formation of SnO in an ethanol-water solvent system was evaluated.	Ethanol	54-61	strawberry notch homolog 1	Homo sapiens	44-47
29894849-5	2018	The possible mechanism for the formation of SnO in an ethanol-water solvent system was evaluated.	Water	62-67	strawberry notch homolog 1	Homo sapiens	44-47
29894849-6	2018	Furthermore, a light was shed on the factors responsible for the pico size of SnO particles synthesis along with its phenomenal distribution on the GO-AMBA surface.	go-amba	148-155	strawberry notch homolog 1	Homo sapiens	78-81
29894849-7	2018	The catalyst containing SnO PPs was deployed as a biosensor for the detection of ascorbic acid (AA) for the very first time.	Ascorbic Acid	81-94	strawberry notch homolog 1	Homo sapiens	24-27
30130092-2	2018	In this study, we introduce a heater-switching, pulse-driven, micro gas sensor composed of a microheater and a sensor electrode fabricated with Pd-SnO2-clustered nanoparticles as the sensing material.	Palladium	144-146	strawberry notch homolog 1	Homo sapiens	147-150
31458911-3	2018	High-resolution transmission electron microscopy images show the close contacts between SnO2-ZnO QDs with the g-C3N4 in the ternary SnO2-ZnO QDs/g-C3N4 hybrid.	Zinc Oxide	93-96	strawberry notch homolog 1	Homo sapiens	88-91
30207366-0	2018	Tin(ii) oxide carbodiimide and its relationship to SnO.	tin(ii) oxide carbodiimide	0-26	strawberry notch homolog 1	Homo sapiens	51-54
30207366-1	2018	The compound Sn2O(CN2) was obtained as a brick-red crystalline powder from a solid-state reaction of equimolar amounts of SnCl2, SnO and Li2(CN2).	sn2o	13-17	strawberry notch homolog 1	Homo sapiens	129-132
30207366-4	2018	The crystal structure of Sn2O(CN2) is analyzed and discussed in relation to that of SnO, namely by electronic-structure calculations and a COHP bonding analysis of Sn2O(CN2).	sn2o	25-29	strawberry notch homolog 1	Homo sapiens	84-87
30104357-4	2018	Electrochemically lithiated SmNiO3 (Li-SNO) contains a large amount of mobile Li+ located in interstitial sites of the perovskite approaching one dopant ion per unit cell.	smnio3	28-34	strawberry notch homolog 1	Homo sapiens	39-42
30104357-4	2018	Electrochemically lithiated SmNiO3 (Li-SNO) contains a large amount of mobile Li+ located in interstitial sites of the perovskite approaching one dopant ion per unit cell.	perovskite	119-129	strawberry notch homolog 1	Homo sapiens	39-42
29677807-0	2018	Electrochemical Properties of Micron-Sized SnO Anode Using a Glyme-Based Electrolyte for Sodium-Ion Battery.	1,2-dimethoxyethane	61-66	strawberry notch homolog 1	Homo sapiens	43-46
29677807-0	2018	Electrochemical Properties of Micron-Sized SnO Anode Using a Glyme-Based Electrolyte for Sodium-Ion Battery.	Sodium	89-95	strawberry notch homolog 1	Homo sapiens	43-46
29677807-1	2018	Tin monoxide (SnO) anodes are promising candidates for use in sodium-ion batteries because of their high theoretical capacities and stable cycle performance.	Tin(II) oxide	0-12	strawberry notch homolog 1	Homo sapiens	14-17
29677807-1	2018	Tin monoxide (SnO) anodes are promising candidates for use in sodium-ion batteries because of their high theoretical capacities and stable cycle performance.	Sodium	62-68	strawberry notch homolog 1	Homo sapiens	14-17
29677807-9	2018	The electrode composed of micron-sized SnO is a potential candidate for use in sodium-ion batteries.	Sodium	79-85	strawberry notch homolog 1	Homo sapiens	39-42
31458911-5	2018	The enriched charge-carrier separation and transportation in the SnO2-ZnO QDs/g-C3N4 hybrid was determined based on electrochemical impedance and photocurrent analyses.	Zinc Oxide	70-73	strawberry notch homolog 1	Homo sapiens	65-68
31458911-6	2018	This remarkable photoactivity is ascribed to the "smart" heterostructure, which yields numerous benefits, such as visible-light-driven fast electron and hole transfer, due to the strong interaction between the SnO2-ZnO QDs with the g-C3N4 matrix.	Zinc Oxide	215-218	strawberry notch homolog 1	Homo sapiens	210-213
29905753-0	2018	Porous Co3O4/SnO2 quantum dot (QD) heterostructures with abundant oxygen vacancies and Co2+ ions for highly efficient gas sensing and oxygen evolution reaction.	Oxygen	66-72	strawberry notch homolog 1	Homo sapiens	13-16
29667935-1	2018	Three-dimensional (3D) SnO hierarchical architectures were synthesized via a one-step dissolution-precipitation route under room temperature using SnCl2   2H2O and Na2CO3 as the initial reagents.	stannous chloride	147-159	strawberry notch homolog 1	Homo sapiens	23-26
29667935-1	2018	Three-dimensional (3D) SnO hierarchical architectures were synthesized via a one-step dissolution-precipitation route under room temperature using SnCl2   2H2O and Na2CO3 as the initial reagents.	sodium carbonate	164-170	strawberry notch homolog 1	Homo sapiens	23-26
29667935-2	2018	The morphology and size of the prepared SnO structures could be easily tailored by alternating the solvent from deionized water with absolute ethanol.	Water	122-127	strawberry notch homolog 1	Homo sapiens	40-43
29667935-2	2018	The morphology and size of the prepared SnO structures could be easily tailored by alternating the solvent from deionized water with absolute ethanol.	Ethanol	142-149	strawberry notch homolog 1	Homo sapiens	40-43
29667935-4	2018	The size of the SnO hierarchical architectures could be effectively reduced from 4-10 mum to 1-2 mum when the solvent was changed from water to ethanol while the thickness of the assembling nanosheets was reduced from 200-500 nm to 20-30 nm at the same time.	Water	135-140	strawberry notch homolog 1	Homo sapiens	16-19
29667935-4	2018	The size of the SnO hierarchical architectures could be effectively reduced from 4-10 mum to 1-2 mum when the solvent was changed from water to ethanol while the thickness of the assembling nanosheets was reduced from 200-500 nm to 20-30 nm at the same time.	Ethanol	144-151	strawberry notch homolog 1	Homo sapiens	16-19
29667935-6	2018	The photodegradation of methylene blue revealed that the SnO hierarchical structures prepared using ethanol as the solvent exhibit much better photocatalytic activity due to its smaller particle size, larger specific surface area, and appropriate band structure as well.	Methylene Blue	24-38	strawberry notch homolog 1	Homo sapiens	57-60
29667935-6	2018	The photodegradation of methylene blue revealed that the SnO hierarchical structures prepared using ethanol as the solvent exhibit much better photocatalytic activity due to its smaller particle size, larger specific surface area, and appropriate band structure as well.	Ethanol	100-107	strawberry notch homolog 1	Homo sapiens	57-60
29926863-0	2018	Robust band gaps in the graphene/oxide heterostructure: SnO/graphene/SnO.	Graphite	24-32	strawberry notch homolog 1	Homo sapiens	56-59
29926863-0	2018	Robust band gaps in the graphene/oxide heterostructure: SnO/graphene/SnO.	Graphite	24-32	strawberry notch homolog 1	Homo sapiens	69-72
29926863-0	2018	Robust band gaps in the graphene/oxide heterostructure: SnO/graphene/SnO.	Oxides	33-38	strawberry notch homolog 1	Homo sapiens	56-59
29926863-0	2018	Robust band gaps in the graphene/oxide heterostructure: SnO/graphene/SnO.	Oxides	33-38	strawberry notch homolog 1	Homo sapiens	69-72
29926863-2	2018	To overcome this limitation of zero band gap, we consider vertically-stacked heterostructures consisting of graphene and SnO knowing that two-dimensional SnO films were synthesized recently.	Graphite	108-116	strawberry notch homolog 1	Homo sapiens	154-157
29926863-3	2018	Calculations based on density functional theory find that the oxide monolayer can induce a notable band gap in graphene; 115 meV in SnO/graphene/SnO heterostructures.	Oxides	62-67	strawberry notch homolog 1	Homo sapiens	132-135
29926863-3	2018	Calculations based on density functional theory find that the oxide monolayer can induce a notable band gap in graphene; 115 meV in SnO/graphene/SnO heterostructures.	Oxides	62-67	strawberry notch homolog 1	Homo sapiens	145-148
29926863-3	2018	Calculations based on density functional theory find that the oxide monolayer can induce a notable band gap in graphene; 115 meV in SnO/graphene/SnO heterostructures.	Graphite	111-119	strawberry notch homolog 1	Homo sapiens	132-135
29905753-0	2018	Porous Co3O4/SnO2 quantum dot (QD) heterostructures with abundant oxygen vacancies and Co2+ ions for highly efficient gas sensing and oxygen evolution reaction.	Cobalt(2+)	87-91	strawberry notch homolog 1	Homo sapiens	13-16
29926863-3	2018	Calculations based on density functional theory find that the oxide monolayer can induce a notable band gap in graphene; 115 meV in SnO/graphene/SnO heterostructures.	Graphite	111-119	strawberry notch homolog 1	Homo sapiens	145-148
29905753-0	2018	Porous Co3O4/SnO2 quantum dot (QD) heterostructures with abundant oxygen vacancies and Co2+ ions for highly efficient gas sensing and oxygen evolution reaction.	Oxygen	134-140	strawberry notch homolog 1	Homo sapiens	13-16
29905753-1	2018	Porous Co3O4/SnO2 quantum dot (QD) heterojunctions with a strong synergistic effect are successfully synthesized in this paper.	co3o4	7-12	strawberry notch homolog 1	Homo sapiens	13-16
29796570-2	2018	The incorporation of nitrosomercaptopyridine (SNO+) into the cucurbit[7]uril cavity results in a large increase of its nitrosation equilibrium constant.	nitrosomercaptopyridine	21-44	strawberry notch homolog 1	Homo sapiens	46-49
29796570-2	2018	The incorporation of nitrosomercaptopyridine (SNO+) into the cucurbit[7]uril cavity results in a large increase of its nitrosation equilibrium constant.	uril	72-76	strawberry notch homolog 1	Homo sapiens	46-49
29796570-3	2018	This effect being a consequence of the preferential stabilization of organic cations by the formation of host : guest complexes with CB7 results in a drastic reduction of the SNO+ denitrosation rate constant.	cucurbit(7)uril	133-136	strawberry notch homolog 1	Homo sapiens	175-178
29796570-4	2018	Moreover, SNO+ encapsulation also prevents its decomposition yielding disulfide and nitric oxide.	Disulfides	70-79	strawberry notch homolog 1	Homo sapiens	10-13
29796570-4	2018	Moreover, SNO+ encapsulation also prevents its decomposition yielding disulfide and nitric oxide.	Nitric Oxide	84-96	strawberry notch homolog 1	Homo sapiens	10-13
29796570-5	2018	The expulsion of SNO+ from the cucurbituril cavity through the application of a chemical stimulus (competitive binding) results in controlled nitric oxide release as was confirmed by using a NO selective electrode.	cucurbit(n)uril	31-43	strawberry notch homolog 1	Homo sapiens	17-20
29796570-5	2018	The expulsion of SNO+ from the cucurbituril cavity through the application of a chemical stimulus (competitive binding) results in controlled nitric oxide release as was confirmed by using a NO selective electrode.	Nitric Oxide	142-154	strawberry notch homolog 1	Homo sapiens	17-20
29442304-2	2018	The results showed that Ti/SnO2-Sb-Pd-500 could achieve the highest electrochemical activity (87.5% of Ni-EDTA removal efficiency), superior durability (50.7 h of accelerated lifetime), and higher Ni recovery (19.8%) on cathode.	Titanium	24-26	strawberry notch homolog 1	Homo sapiens	27-30
29482942-3	2018	1,3,2-Oxathiazolylium-5-olates (OZOs) represent an interesting subclass of S-nitrosothiols that lock the -SNO moiety into a five membered heterocyclic ring in an attempt to improve the compound"s overall stability.	1,3,2-oxathiazolylium-5-olates	0-30	strawberry notch homolog 1	Homo sapiens	106-109
29482942-3	2018	1,3,2-Oxathiazolylium-5-olates (OZOs) represent an interesting subclass of S-nitrosothiols that lock the -SNO moiety into a five membered heterocyclic ring in an attempt to improve the compound"s overall stability.	ozos	32-36	strawberry notch homolog 1	Homo sapiens	106-109
29482942-3	2018	1,3,2-Oxathiazolylium-5-olates (OZOs) represent an interesting subclass of S-nitrosothiols that lock the -SNO moiety into a five membered heterocyclic ring in an attempt to improve the compound"s overall stability.	S-Nitrosothiols	75-90	strawberry notch homolog 1	Homo sapiens	106-109
29442304-2	2018	The results showed that Ti/SnO2-Sb-Pd-500 could achieve the highest electrochemical activity (87.5% of Ni-EDTA removal efficiency), superior durability (50.7 h of accelerated lifetime), and higher Ni recovery (19.8%) on cathode.	Ni EDTA	103-110	strawberry notch homolog 1	Homo sapiens	27-30
29442304-5	2018	Ti/SnO2-Sb-Pd-500 achieved the highest electrochemical capacity with the highest levels of adsorbed oxygen Oads/ET (27.11%) and lattice oxygen Olat/ET (29.69%).	Titanium	0-2	strawberry notch homolog 1	Homo sapiens	3-6
29442304-5	2018	Ti/SnO2-Sb-Pd-500 achieved the highest electrochemical capacity with the highest levels of adsorbed oxygen Oads/ET (27.11%) and lattice oxygen Olat/ET (29.69%).	Oxygen	100-106	strawberry notch homolog 1	Homo sapiens	3-6
29442304-5	2018	Ti/SnO2-Sb-Pd-500 achieved the highest electrochemical capacity with the highest levels of adsorbed oxygen Oads/ET (27.11%) and lattice oxygen Olat/ET (29.69%).	Oxygen	136-142	strawberry notch homolog 1	Homo sapiens	3-6
29327011-0	2018	Highly reversible and fast sodium storage boosted by improved interfacial and surface charge transfer derived from the synergistic effect of heterostructures and pseudocapacitance in SnO2-based anodes.	Sodium	27-33	strawberry notch homolog 1	Homo sapiens	183-186
29560486-4	2018	On further annealing SnO2@HCNBs in Ar, SnO2 is partially reduced to SnOx by consuming a part of carbon of HCNBs as the reducing agent, and thus SnOx@HCNBs are obtained (note that SnOx represents a composite consisting of SnO2, SnO and Sn phases).	Tin(IV) oxide	39-43	strawberry notch homolog 1	Homo sapiens	21-24
29560486-4	2018	On further annealing SnO2@HCNBs in Ar, SnO2 is partially reduced to SnOx by consuming a part of carbon of HCNBs as the reducing agent, and thus SnOx@HCNBs are obtained (note that SnOx represents a composite consisting of SnO2, SnO and Sn phases).	snox	68-72	strawberry notch homolog 1	Homo sapiens	21-24
29560486-4	2018	On further annealing SnO2@HCNBs in Ar, SnO2 is partially reduced to SnOx by consuming a part of carbon of HCNBs as the reducing agent, and thus SnOx@HCNBs are obtained (note that SnOx represents a composite consisting of SnO2, SnO and Sn phases).	Carbon	96-102	strawberry notch homolog 1	Homo sapiens	21-24
29560486-4	2018	On further annealing SnO2@HCNBs in Ar, SnO2 is partially reduced to SnOx by consuming a part of carbon of HCNBs as the reducing agent, and thus SnOx@HCNBs are obtained (note that SnOx represents a composite consisting of SnO2, SnO and Sn phases).	hcnbs	26-31	strawberry notch homolog 1	Homo sapiens	21-24
29560486-4	2018	On further annealing SnO2@HCNBs in Ar, SnO2 is partially reduced to SnOx by consuming a part of carbon of HCNBs as the reducing agent, and thus SnOx@HCNBs are obtained (note that SnOx represents a composite consisting of SnO2, SnO and Sn phases).	snox	144-148	strawberry notch homolog 1	Homo sapiens	21-24
29560486-4	2018	On further annealing SnO2@HCNBs in Ar, SnO2 is partially reduced to SnOx by consuming a part of carbon of HCNBs as the reducing agent, and thus SnOx@HCNBs are obtained (note that SnOx represents a composite consisting of SnO2, SnO and Sn phases).	snox	144-148	strawberry notch homolog 1	Homo sapiens	21-24
29560486-4	2018	On further annealing SnO2@HCNBs in Ar, SnO2 is partially reduced to SnOx by consuming a part of carbon of HCNBs as the reducing agent, and thus SnOx@HCNBs are obtained (note that SnOx represents a composite consisting of SnO2, SnO and Sn phases).	Tin(IV) oxide	39-43	strawberry notch homolog 1	Homo sapiens	21-24
29054002-7	2018	Density functional theory calculations also reveal that the presence of Vos is responsible for the upshift of valence band maximum and an extended conduction band minimum, hence a valence band width broadening and band gap narrowing which consequently enhance the photocatalytic performance of the oxygen-deficient SnO2-x.	vos	72-75	strawberry notch homolog 1	Homo sapiens	315-318
29054002-7	2018	Density functional theory calculations also reveal that the presence of Vos is responsible for the upshift of valence band maximum and an extended conduction band minimum, hence a valence band width broadening and band gap narrowing which consequently enhance the photocatalytic performance of the oxygen-deficient SnO2-x.	Oxygen	298-304	strawberry notch homolog 1	Homo sapiens	315-318
29322769-0	2018	Composition, Microstructure, and Electrical Performance of Sputtered SnO Thin Films for p-Type Oxide Semiconductor.	Oxides	95-100	strawberry notch homolog 1	Homo sapiens	69-72
29322769-1	2018	p-Type SnO thin films were deposited on a Si substrate by a cosputtering process using ceramic SnO and metal Sn targets at room temperature without adding oxygen.	Silicon	42-44	strawberry notch homolog 1	Homo sapiens	7-10
29322769-1	2018	p-Type SnO thin films were deposited on a Si substrate by a cosputtering process using ceramic SnO and metal Sn targets at room temperature without adding oxygen.	Metals	103-108	strawberry notch homolog 1	Homo sapiens	7-10
29600453-1	2018	S-nitrosylation (or S-nitrosation, SNO) is an oxidative posttranslational modification to the thiol group of a cysteine amino acid residue.	Sulfhydryl Compounds	94-99	strawberry notch homolog 1	Homo sapiens	35-38
29600453-1	2018	S-nitrosylation (or S-nitrosation, SNO) is an oxidative posttranslational modification to the thiol group of a cysteine amino acid residue.	cysteine amino acid	111-130	strawberry notch homolog 1	Homo sapiens	35-38
29600453-2	2018	There are several methods to detect SNO modifications, mostly based on the classic biotin-switch assay, where the labile SNO sites are replaced with a stable biotin moiety to facilitate enrichment of the modified proteins.	Biotin	83-89	strawberry notch homolog 1	Homo sapiens	36-39
29600453-2	2018	There are several methods to detect SNO modifications, mostly based on the classic biotin-switch assay, where the labile SNO sites are replaced with a stable biotin moiety to facilitate enrichment of the modified proteins.	Biotin	83-89	strawberry notch homolog 1	Homo sapiens	121-124
29600453-2	2018	There are several methods to detect SNO modifications, mostly based on the classic biotin-switch assay, where the labile SNO sites are replaced with a stable biotin moiety to facilitate enrichment of the modified proteins.	Biotin	158-164	strawberry notch homolog 1	Homo sapiens	36-39
28835961-2	2017	Intramolecular S-S bonds are photogenerated from SNO in the protein, which can be used to photo-control the structure and function of proteins.	Sulfur	15-16	strawberry notch homolog 1	Homo sapiens	49-52
29166608-6	2017	SNO-PINK1 decreases Parkin translocation to mitochondrial membranes, disrupting mitophagy in cell lines and human-iPSC-derived neurons.	profenamine	20-26	strawberry notch homolog 1	Homo sapiens	0-3
29019462-0	2017	Stability and electronic properties of hybrid SnO bilayers: SnO/graphene and SnO/BN.	Graphite	64-72	strawberry notch homolog 1	Homo sapiens	46-49
29019462-0	2017	Stability and electronic properties of hybrid SnO bilayers: SnO/graphene and SnO/BN.	6-bromo-2-naphthyl sulfate	81-83	strawberry notch homolog 1	Homo sapiens	46-49
29019462-4	2017	The calculated results find that the properties of the constituent monolayers are retained in these SnO-based heterostructures, and a p-type Schottky barrier is formed in the SnO/graphene heterostructure.	Graphite	179-187	strawberry notch homolog 1	Homo sapiens	175-178
29019462-6	2017	In the SnO/BN heterostructure, the electronic properties of SnO are least affected by the insulating monolayer suggesting that the BN monolayer would be an ideal substrate for SnO-based nanoscale devices.	6-bromo-2-naphthyl sulfate	11-13	strawberry notch homolog 1	Homo sapiens	60-63
29019462-6	2017	In the SnO/BN heterostructure, the electronic properties of SnO are least affected by the insulating monolayer suggesting that the BN monolayer would be an ideal substrate for SnO-based nanoscale devices.	6-bromo-2-naphthyl sulfate	11-13	strawberry notch homolog 1	Homo sapiens	60-63
28835961-2	2017	Intramolecular S-S bonds are photogenerated from SNO in the protein, which can be used to photo-control the structure and function of proteins.	Sulfur	17-18	strawberry notch homolog 1	Homo sapiens	49-52
28731318-0	2017	Ultrafast Ionic Liquid-Assisted Microwave Synthesis of SnO Microflowers and Their Superior Sodium-Ion Storage Performance.	Sodium	91-97	strawberry notch homolog 1	Homo sapiens	55-58
28864180-5	2017	The proposed method is able to classify NO from DETA-NONOate or (Z)-1-[N-(2-aminoethyl)-N-(2-ammonioethyl) amino] diazen-1-ium-1,2-diolate, nitrite, nitrate and S-nitrosothiol or SNO.	2,2'-(hydroxynitrosohydrazono)bis-ethanamine	48-60	strawberry notch homolog 1	Homo sapiens	179-182
28864180-6	2017	This discrimination is carried out by chlorophyll a (chl a) at nano molar (nM) order of sensitivity and at 293 K-310 K. Molecular docking reveals the differential binding effects of NO and SNO with chlorophyll, the predicted binding affinity matching with the experimental observation.	chlorophyll a	38-51	strawberry notch homolog 1	Homo sapiens	189-192
28864180-6	2017	This discrimination is carried out by chlorophyll a (chl a) at nano molar (nM) order of sensitivity and at 293 K-310 K. Molecular docking reveals the differential binding effects of NO and SNO with chlorophyll, the predicted binding affinity matching with the experimental observation.	Chlorophyll	38-49	strawberry notch homolog 1	Homo sapiens	189-192
28795808-1	2017	SNO-OCTs are eight-membered heterocyclic alkynes that have fast rates of reactivity with 1,3-dipoles.	Alkynes	41-48	strawberry notch homolog 1	Homo sapiens	0-3
28795808-1	2017	SNO-OCTs are eight-membered heterocyclic alkynes that have fast rates of reactivity with 1,3-dipoles.	1,3-dipoles	89-100	strawberry notch homolog 1	Homo sapiens	0-3
28795808-2	2017	In contrast to many other reported cycloalkynes, SNO-OCTs contain multiple sites for derivatization, display stability under a variety of common reaction conditions, and offer the opportunity for strain-induced ring-opening following the initial reaction of the alkyne moiety.	Cycloparaffins	35-47	strawberry notch homolog 1	Homo sapiens	49-52
28795808-2	2017	In contrast to many other reported cycloalkynes, SNO-OCTs contain multiple sites for derivatization, display stability under a variety of common reaction conditions, and offer the opportunity for strain-induced ring-opening following the initial reaction of the alkyne moiety.	Alkynes	40-46	strawberry notch homolog 1	Homo sapiens	49-52
28795808-3	2017	In this paper, we describe how the unique features of SNO-OCTs can be employed to modify an oxime-bearing styrene copolymer and introduce an array of polar functionalities into the polymer.	Oximes	92-97	strawberry notch homolog 1	Homo sapiens	54-57
28795808-3	2017	In this paper, we describe how the unique features of SNO-OCTs can be employed to modify an oxime-bearing styrene copolymer and introduce an array of polar functionalities into the polymer.	styrofoam	106-123	strawberry notch homolog 1	Homo sapiens	54-57
28816457-0	2017	A Coupled Cluster Investigation of SNO Radical Isomers and Their Reactions with Hydrogen Atom: Insight into Structures, Conformers, Barriers, and Energetics.	Hydrogen	80-88	strawberry notch homolog 1	Homo sapiens	35-38
28816457-4	2017	The CCSD(T)/aug-cc-pV5Z//CCSD(T)/aug-cc-pVTZ results suggest that the reaction between SNO radical isomers and hydrogen atom result in the formation of their [H,N,S,O] hydrides with HNSO hydrides being the most stable ones.	Hydrogen	111-119	strawberry notch homolog 1	Homo sapiens	87-90
28731318-1	2017	Tin oxide (SnO) is considered one of the most promising metal oxides for utilization as anode material in sodium ion batteries (SIBs), because of its ease of synthesis, high specific gravimetric capacity, and satisfactory cycling performance.	stannic oxide	0-9	strawberry notch homolog 1	Homo sapiens	11-14
28731318-1	2017	Tin oxide (SnO) is considered one of the most promising metal oxides for utilization as anode material in sodium ion batteries (SIBs), because of its ease of synthesis, high specific gravimetric capacity, and satisfactory cycling performance.	metal oxides	56-68	strawberry notch homolog 1	Homo sapiens	11-14
28566756-0	2017	Layer-dependent semiconductor-metal transition of SnO/Si(001) heterostructure and device application.	Metals	30-35	strawberry notch homolog 1	Homo sapiens	50-53
28688423-0	2017	Photoelectron spectroscopy of the thiazate (NSO-) and thionitrite (SNO-) isomer anions.	thionitrite	54-65	strawberry notch homolog 1	Homo sapiens	67-70
28688423-1	2017	Anion photoelectron spectra of the thiazate (NSO-) and thionitrite (SNO-) isomers are reported.	thionitrite	55-66	strawberry notch homolog 1	Homo sapiens	68-71
28688423-8	2017	In addition to the spectrally congested spectrum, there was evidence of a competition between photodetachment from SNO- and SNO- photodissociation to form S- + NO.	Nobelium	155-162	strawberry notch homolog 1	Homo sapiens	115-118
28688423-8	2017	In addition to the spectrally congested spectrum, there was evidence of a competition between photodetachment from SNO- and SNO- photodissociation to form S- + NO.	Nobelium	155-162	strawberry notch homolog 1	Homo sapiens	124-127
28288376-0	2017	Facile fabrication of Dy(2)Sn(2)O(7)-SnO(2) nanocomposites as an effective photocatalyst for degradation and removal of organic contaminants.	dy(2)sn(2)o(7)	22-36	strawberry notch homolog 1	Homo sapiens	37-40
28382373-7	2017	The proadhesive effects of inhibiting LAT1 could be overcome by supplemental L-CSNO (S-nitroso-L-cysteine), but not D-CSNO or L-Cys, and suggest a basal anti-adhesive role for stereospecific intercellular SNO transport.	S-nitrosocysteine	85-105	strawberry notch homolog 1	Homo sapiens	80-83
28388028-5	2017	Here, we investigate the interplay between QD dipolar molecular capping, interfacial QD-oxide ET rates, and QD workfunction in PbS QD/SnO2-sensitized interfaces.	Lead	127-130	strawberry notch homolog 1	Homo sapiens	134-137
28566756-3	2017	Here, we propose an interesting heterostructure made of ultrathin SnO layers on Si(001) surface.	Silicon	80-82	strawberry notch homolog 1	Homo sapiens	66-69
28566756-4	2017	Our first-principle calculations show that a single layer of SnO on Si(001) surface is a semiconductor, but a bilayer SnO on the same surface is metallic.	Silicon	68-70	strawberry notch homolog 1	Homo sapiens	61-64
28566756-6	2017	In particular, due to the interaction between Sn and the Si substrate, the semiconducting monolayer-SnO/Si(001) has a highly anisotropic band structure with a much lighter hole effective mass along one direction than that of Si and most other 2D materials, indicating a high carrier mobility.	Tin	46-48	strawberry notch homolog 1	Homo sapiens	100-103
28566756-6	2017	In particular, due to the interaction between Sn and the Si substrate, the semiconducting monolayer-SnO/Si(001) has a highly anisotropic band structure with a much lighter hole effective mass along one direction than that of Si and most other 2D materials, indicating a high carrier mobility.	Silicon	57-59	strawberry notch homolog 1	Homo sapiens	100-103
28566756-6	2017	In particular, due to the interaction between Sn and the Si substrate, the semiconducting monolayer-SnO/Si(001) has a highly anisotropic band structure with a much lighter hole effective mass along one direction than that of Si and most other 2D materials, indicating a high carrier mobility.	Silicon	104-106	strawberry notch homolog 1	Homo sapiens	100-103
28566756-6	2017	In particular, due to the interaction between Sn and the Si substrate, the semiconducting monolayer-SnO/Si(001) has a highly anisotropic band structure with a much lighter hole effective mass along one direction than that of Si and most other 2D materials, indicating a high carrier mobility.	Silicon	104-106	strawberry notch homolog 1	Homo sapiens	100-103
28566756-6	2017	In particular, due to the interaction between Sn and the Si substrate, the semiconducting monolayer-SnO/Si(001) has a highly anisotropic band structure with a much lighter hole effective mass along one direction than that of Si and most other 2D materials, indicating a high carrier mobility.	Echothiophate Iodide	243-245	strawberry notch homolog 1	Homo sapiens	100-103
28772679-2	2017	In this work, a ring oscillator based on n-type indium-gallium-zinc-oxide (IGZO) and p-type tin monoxide (SnO) is presented.	Tin(II) oxide	92-104	strawberry notch homolog 1	Homo sapiens	106-109
28382204-0	2017	Nitrosopersulfide (SSNO-) decomposes in the presence of sulfide, cyanide or glutathione to give HSNO/SNO-: consequences for the assumed role in cell signalling.	nitrosopersulfide	0-17	strawberry notch homolog 1	Homo sapiens	20-23
28382204-0	2017	Nitrosopersulfide (SSNO-) decomposes in the presence of sulfide, cyanide or glutathione to give HSNO/SNO-: consequences for the assumed role in cell signalling.	Sulfides	10-17	strawberry notch homolog 1	Homo sapiens	20-23
28382204-0	2017	Nitrosopersulfide (SSNO-) decomposes in the presence of sulfide, cyanide or glutathione to give HSNO/SNO-: consequences for the assumed role in cell signalling.	Cyanides	65-72	strawberry notch homolog 1	Homo sapiens	20-23
28382204-0	2017	Nitrosopersulfide (SSNO-) decomposes in the presence of sulfide, cyanide or glutathione to give HSNO/SNO-: consequences for the assumed role in cell signalling.	Glutathione	76-87	strawberry notch homolog 1	Homo sapiens	20-23
28382204-0	2017	Nitrosopersulfide (SSNO-) decomposes in the presence of sulfide, cyanide or glutathione to give HSNO/SNO-: consequences for the assumed role in cell signalling.	S-nitroso-2-mercaptoethylamine	96-100	strawberry notch homolog 1	Homo sapiens	20-23
28382204-8	2017	In this study, we work with pure PNP+SSNO- to show that contrary to everything that is claimed for the yellow reaction product of GSNO with H2S, pure SSNO- decomposes readily in the presence of cyanide, H2S and glutathione to form SNO-.	ssno	150-154	strawberry notch homolog 1	Homo sapiens	38-41
28772679-5	2017	The three-stage ring oscillator based on IGZO and SnO is able to operate at 2.63 kHz and the peak-to-peak oscillation amplitude reaches 36.1 V at a supply voltage of 40 V. The oxide-based complementary circuits, after further optimization of the operation voltage, may have wide applications in practical large-area flexible electronics.	Oxides	176-181	strawberry notch homolog 1	Homo sapiens	50-53
28262673-3	2017	The results indicated that the formation of Fe3-xSnxO4 could be divided into four steps: reduction of SnO2 to solid phase SnO, volatilization of gaseous SnO, adsorption of gaseous SnO on the surface of Fe3O4, and redox reaction between SnO and Fe3O4.	fe3-xsnxo4	44-54	strawberry notch homolog 1	Homo sapiens	102-105
28262673-3	2017	The results indicated that the formation of Fe3-xSnxO4 could be divided into four steps: reduction of SnO2 to solid phase SnO, volatilization of gaseous SnO, adsorption of gaseous SnO on the surface of Fe3O4, and redox reaction between SnO and Fe3O4.	fe3-xsnxo4	44-54	strawberry notch homolog 1	Homo sapiens	122-125
28262673-3	2017	The results indicated that the formation of Fe3-xSnxO4 could be divided into four steps: reduction of SnO2 to solid phase SnO, volatilization of gaseous SnO, adsorption of gaseous SnO on the surface of Fe3O4, and redox reaction between SnO and Fe3O4.	fe3-xsnxo4	44-54	strawberry notch homolog 1	Homo sapiens	122-125
28262673-3	2017	The results indicated that the formation of Fe3-xSnxO4 could be divided into four steps: reduction of SnO2 to solid phase SnO, volatilization of gaseous SnO, adsorption of gaseous SnO on the surface of Fe3O4, and redox reaction between SnO and Fe3O4.	fe3-xsnxo4	44-54	strawberry notch homolog 1	Homo sapiens	122-125
28262673-4	2017	During the roasting process, part of Fe3+ in Fe3O4 was reduced to Fe2+ by gaseous SnO, and meanwhile Sn2+ was oxidized to Sn4+ and entered into Fe3-xSnxO4.	ferric sulfate	37-41	strawberry notch homolog 1	Homo sapiens	82-85
28262673-4	2017	During the roasting process, part of Fe3+ in Fe3O4 was reduced to Fe2+ by gaseous SnO, and meanwhile Sn2+ was oxidized to Sn4+ and entered into Fe3-xSnxO4.	ferryl iron	45-50	strawberry notch homolog 1	Homo sapiens	82-85
28262673-4	2017	During the roasting process, part of Fe3+ in Fe3O4 was reduced to Fe2+ by gaseous SnO, and meanwhile Sn2+ was oxidized to Sn4+ and entered into Fe3-xSnxO4.	ammonium ferrous sulfate	66-70	strawberry notch homolog 1	Homo sapiens	82-85
27912190-0	2017	Nanostructured 3D-porous graphene hydrogel based Ti/Sb-SnO2-Gr electrode with enhanced electrocatalytic activity.	Graphite	25-33	strawberry notch homolog 1	Homo sapiens	55-58
28098459-0	2017	Two-Dimensional SnO Anodes with a Tunable Number of Atomic Layers for Sodium Ion Batteries.	Sodium	70-76	strawberry notch homolog 1	Homo sapiens	16-19
27912190-1	2017	Nanostructured highly porous 3D-Ti/Sb-SnO2-Gr electrode, based on 3D porous graphene hydrogel was fabricated via a fast-evaporation technique through layer by layer (LBL) deposition.	Graphite	76-84	strawberry notch homolog 1	Homo sapiens	38-41
27912190-4	2017	Electrocatalytic oxidation of Rhodamine B (RhB) was employed to evaluate the efficiency of the fabricated 3D-Ti/Sb-SnO2-Gr anode.	rhodamine B	30-41	strawberry notch homolog 1	Homo sapiens	115-118
27912190-4	2017	Electrocatalytic oxidation of Rhodamine B (RhB) was employed to evaluate the efficiency of the fabricated 3D-Ti/Sb-SnO2-Gr anode.	rhodamine B	43-46	strawberry notch homolog 1	Homo sapiens	115-118
28144570-1	2017	The aim of this research is to study the role of nanocrystalline TiO2/SnO2 n-n heterojunctions for hydrogen sensing.	Hydrogen	99-107	strawberry notch homolog 1	Homo sapiens	70-73
28144570-8	2017	The recovery time of SnO2-based heterostructures, despite their large responses over the whole measuring range, is much longer than that of TiO2-rich samples at higher H2 flows.	Hydrogen	168-170	strawberry notch homolog 1	Homo sapiens	21-24
27282318-1	2016	A visible-light-active carbon nitride (CN)/strontium pyroniobate (SNO) heterojunction photocatalyst was fabricated by deposition of CN over hydrothermally synthesized SNO nanoplates by a simple thermal decomposition process.	cyanogen	23-37	strawberry notch homolog 1	Homo sapiens	167-170
27801452-0	2016	Aerosol-assisted CVD of SnO from stannous alkoxide precursors.	stannous alkoxide	33-50	strawberry notch homolog 1	Homo sapiens	24-27
27801452-4	2016	The previously reported iso-propoxide (1) and tert-butoxide (2) derivatives have been utilised in toluene solution to deposit SnO thin films by aerosol-assisted chemical vapour deposition (AACVD) on glass at temperatures between 300 and 450  C. While SnO is deposited under hot wall conditions as the only identifiable phase by p-XRD and Raman spectroscopy for both precursors, morphological analysis by SEM reveals inferior substrate coverage in comparison to previously reported ureide-based precursor systems.	iso-propoxide	24-37	strawberry notch homolog 1	Homo sapiens	126-129
27801452-4	2016	The previously reported iso-propoxide (1) and tert-butoxide (2) derivatives have been utilised in toluene solution to deposit SnO thin films by aerosol-assisted chemical vapour deposition (AACVD) on glass at temperatures between 300 and 450  C. While SnO is deposited under hot wall conditions as the only identifiable phase by p-XRD and Raman spectroscopy for both precursors, morphological analysis by SEM reveals inferior substrate coverage in comparison to previously reported ureide-based precursor systems.	iso-propoxide	24-37	strawberry notch homolog 1	Homo sapiens	251-254
27801452-4	2016	The previously reported iso-propoxide (1) and tert-butoxide (2) derivatives have been utilised in toluene solution to deposit SnO thin films by aerosol-assisted chemical vapour deposition (AACVD) on glass at temperatures between 300 and 450  C. While SnO is deposited under hot wall conditions as the only identifiable phase by p-XRD and Raman spectroscopy for both precursors, morphological analysis by SEM reveals inferior substrate coverage in comparison to previously reported ureide-based precursor systems.	2-methylpropan-2-olate	46-59	strawberry notch homolog 1	Homo sapiens	126-129
27801452-4	2016	The previously reported iso-propoxide (1) and tert-butoxide (2) derivatives have been utilised in toluene solution to deposit SnO thin films by aerosol-assisted chemical vapour deposition (AACVD) on glass at temperatures between 300 and 450  C. While SnO is deposited under hot wall conditions as the only identifiable phase by p-XRD and Raman spectroscopy for both precursors, morphological analysis by SEM reveals inferior substrate coverage in comparison to previously reported ureide-based precursor systems.	Toluene	98-105	strawberry notch homolog 1	Homo sapiens	126-129
27801452-4	2016	The previously reported iso-propoxide (1) and tert-butoxide (2) derivatives have been utilised in toluene solution to deposit SnO thin films by aerosol-assisted chemical vapour deposition (AACVD) on glass at temperatures between 300 and 450  C. While SnO is deposited under hot wall conditions as the only identifiable phase by p-XRD and Raman spectroscopy for both precursors, morphological analysis by SEM reveals inferior substrate coverage in comparison to previously reported ureide-based precursor systems.	Toluene	98-105	strawberry notch homolog 1	Homo sapiens	251-254
27295323-5	2016	With the increasing in RE ionic radius (r), the SnO bond strength in Ln2Sn2O7 pyrochlores evaluated from the stretching IR band was decreased, resulting in the improved reducibility and enhanced oxygen vacancies of catalysts.	ln2sn2o7 pyrochlores	69-89	strawberry notch homolog 1	Homo sapiens	48-51
27295323-5	2016	With the increasing in RE ionic radius (r), the SnO bond strength in Ln2Sn2O7 pyrochlores evaluated from the stretching IR band was decreased, resulting in the improved reducibility and enhanced oxygen vacancies of catalysts.	Oxygen	195-201	strawberry notch homolog 1	Homo sapiens	48-51
27282318-1	2016	A visible-light-active carbon nitride (CN)/strontium pyroniobate (SNO) heterojunction photocatalyst was fabricated by deposition of CN over hydrothermally synthesized SNO nanoplates by a simple thermal decomposition process.	cyanogen	39-41	strawberry notch homolog 1	Homo sapiens	167-170
27282318-1	2016	A visible-light-active carbon nitride (CN)/strontium pyroniobate (SNO) heterojunction photocatalyst was fabricated by deposition of CN over hydrothermally synthesized SNO nanoplates by a simple thermal decomposition process.	strontium pyroniobate	43-64	strawberry notch homolog 1	Homo sapiens	66-69
27282318-1	2016	A visible-light-active carbon nitride (CN)/strontium pyroniobate (SNO) heterojunction photocatalyst was fabricated by deposition of CN over hydrothermally synthesized SNO nanoplates by a simple thermal decomposition process.	strontium pyroniobate	43-64	strawberry notch homolog 1	Homo sapiens	167-170
27282318-5	2016	Specifically, the photocatalytic hydrogen evolution rate per mole of CN was found to be 11 times higher for the CN/SNO composite compared to pristine CN.	Hydrogen	33-41	strawberry notch homolog 1	Homo sapiens	115-118
26960016-3	2016	Using a combination of solution (119)Sn NMR and Raman spectroscopies, bis(1,2-ethanedithiolate)tin(II) was identified as the likely molecular solute present after the dissolution of Sn, SnO, and SnS in EDT-en, despite the different bulk material compositions and oxidation states (Sn(0) and Sn(2+)).	bis(1,2-ethanedithiolate)tin	70-98	strawberry notch homolog 1	Homo sapiens	186-189
27441283-1	2016	A study was conducted on the transformation of SnO to SnO2 using X-ray diffraction and subjecting the SnO to heat treatments between 300  C &lt; T &lt; 600  C in two different atmospheres, argon and air.	Argon	189-194	strawberry notch homolog 1	Homo sapiens	47-50
27441283-1	2016	A study was conducted on the transformation of SnO to SnO2 using X-ray diffraction and subjecting the SnO to heat treatments between 300  C &lt; T &lt; 600  C in two different atmospheres, argon and air.	Argon	189-194	strawberry notch homolog 1	Homo sapiens	54-57
27812462-3	2016	Nanosized Sn-Fe-C anode materials are mechanochemically synthesized by reducing SnO with Ti in the presence of carbon.	sn-fe-c	10-17	strawberry notch homolog 1	Homo sapiens	80-83
26964735-0	2016	Co3O4-SnO2 Hollow Heteronanostructures: Facile Control of Gas Selectivity by Compositional Tuning of Sensing Materials via Galvanic Replacement.	co3o4	0-5	strawberry notch homolog 1	Homo sapiens	6-9
26694397-6	2015	The sensor output of the micro-TGS decreased with increasing Pt content in the Pt/alpha-Al2O3 catalyst, by cancelling out the combustion heat from the AuPtPd/SnO2 catalyst.	Platinum	61-63	strawberry notch homolog 1	Homo sapiens	158-161
26518762-2	2016	The nucleophilic thiol group allows cysteine to undergo a broad range of redox modifications beyond classical thiol-disulfide redox equilibria, including S-sulfenylation (-SOH), S-sulfinylation (-SO(2)H), S-sulfonylation (-SO(3)H), S-nitrosylation (-SNO), S-sulfhydration (-SSH), S-glutathionylation (-SSG), and others.	Sulfhydryl Compounds	17-22	strawberry notch homolog 1	Homo sapiens	250-253
26518762-2	2016	The nucleophilic thiol group allows cysteine to undergo a broad range of redox modifications beyond classical thiol-disulfide redox equilibria, including S-sulfenylation (-SOH), S-sulfinylation (-SO(2)H), S-sulfonylation (-SO(3)H), S-nitrosylation (-SNO), S-sulfhydration (-SSH), S-glutathionylation (-SSG), and others.	Cysteine	36-44	strawberry notch homolog 1	Homo sapiens	250-253
26073320-7	2016	Sno-lncRNAs likewise lack poly(A) tails and instead have snoRNA structures at their 5" and 3" ends.	Poly A	26-33	strawberry notch homolog 1	Homo sapiens	0-3
28191419-0	2016	Electrochemical properties of Sn-decorated SnO nanobranches as an anode of Li-ion battery.	Tin	30-32	strawberry notch homolog 1	Homo sapiens	43-46
28191419-4	2016	Through the morphological and crystal structure analyses after the charge and discharge processes, it was found that the morphology of Sn-decorated SnO NBs was transformed to nanoporous layered-structure, composed of Sn and lithium oxide, during the repeated lithiation/delithiation reactions.	Tin	135-137	strawberry notch homolog 1	Homo sapiens	148-151
28191419-4	2016	Through the morphological and crystal structure analyses after the charge and discharge processes, it was found that the morphology of Sn-decorated SnO NBs was transformed to nanoporous layered-structure, composed of Sn and lithium oxide, during the repeated lithiation/delithiation reactions.	Lithium oxide	224-237	strawberry notch homolog 1	Homo sapiens	148-151
28191419-5	2016	The free-volume of Sn-decorated SnO NBs and nanoporous layered-structure effectively accommodate the huge volume changes and enhance the electrochemical cyclability by facilitating the diffusion of Li-ions.	Tin	19-21	strawberry notch homolog 1	Homo sapiens	32-35
26694397-6	2015	The sensor output of the micro-TGS decreased with increasing Pt content in the Pt/alpha-Al2O3 catalyst, by cancelling out the combustion heat from the AuPtPd/SnO2 catalyst.	alpha-al2o3	82-93	strawberry notch homolog 1	Homo sapiens	158-161
26694397-6	2015	The sensor output of the micro-TGS decreased with increasing Pt content in the Pt/alpha-Al2O3 catalyst, by cancelling out the combustion heat from the AuPtPd/SnO2 catalyst.	auptpd	151-157	strawberry notch homolog 1	Homo sapiens	158-161
26694397-7	2015	In addition, the AuPtPd/SnO2 and 0.3 wt% Pt/alpha-Al2O3 double catalyst sensor showed good and selective CO detection.	alpha-al2o3	44-55	strawberry notch homolog 1	Homo sapiens	24-27
26553414-0	2015	Phase diagram of the layered oxide SnO: GW and electron-phonon studies.	Oxides	29-34	strawberry notch homolog 1	Homo sapiens	35-38
26228648-2	2015	Herein, we present the construction of an intelligent X-ray-controlled NO-releasing upconversion nanotheranostic system (termed as PEG-USMSs-SNO) by engineering UCNPs with S-nitrosothiol (R-SNO)-grafted mesoporous silica.	peg-usmss	131-140	strawberry notch homolog 1	Homo sapiens	141-144
26228648-2	2015	Herein, we present the construction of an intelligent X-ray-controlled NO-releasing upconversion nanotheranostic system (termed as PEG-USMSs-SNO) by engineering UCNPs with S-nitrosothiol (R-SNO)-grafted mesoporous silica.	peg-usmss	131-140	strawberry notch homolog 1	Homo sapiens	190-193
26228648-2	2015	Herein, we present the construction of an intelligent X-ray-controlled NO-releasing upconversion nanotheranostic system (termed as PEG-USMSs-SNO) by engineering UCNPs with S-nitrosothiol (R-SNO)-grafted mesoporous silica.	S-Nitrosothiols	172-186	strawberry notch homolog 1	Homo sapiens	141-144
26228648-2	2015	Herein, we present the construction of an intelligent X-ray-controlled NO-releasing upconversion nanotheranostic system (termed as PEG-USMSs-SNO) by engineering UCNPs with S-nitrosothiol (R-SNO)-grafted mesoporous silica.	S-Nitrosothiols	172-186	strawberry notch homolog 1	Homo sapiens	190-193
26228648-2	2015	Herein, we present the construction of an intelligent X-ray-controlled NO-releasing upconversion nanotheranostic system (termed as PEG-USMSs-SNO) by engineering UCNPs with S-nitrosothiol (R-SNO)-grafted mesoporous silica.	Silicon Dioxide	214-220	strawberry notch homolog 1	Homo sapiens	141-144
26228648-3	2015	The PEG-USMSs-SNO is designed to respond sensitively to X-ray radiation for breaking down the S-N bond of SNO to release NO, which leads to X-ray dose-controlled NO release for on-demand hypoxic radiosensitization besides upconversion luminescent imaging through UCNPs in vitro and in vivo.	Polyethylene Glycols	4-7	strawberry notch homolog 1	Homo sapiens	14-17
26228648-3	2015	The PEG-USMSs-SNO is designed to respond sensitively to X-ray radiation for breaking down the S-N bond of SNO to release NO, which leads to X-ray dose-controlled NO release for on-demand hypoxic radiosensitization besides upconversion luminescent imaging through UCNPs in vitro and in vivo.	Polyethylene Glycols	4-7	strawberry notch homolog 1	Homo sapiens	106-109
26228648-4	2015	Thanks to the high live-body permeability of X-ray, our developed PEG-USMSs-SNO may provide a new technique for achieving depth-independent controlled NO release and positioned radiotherapy enhancement against deep-seated solid tumors.	peg-usmss	66-75	strawberry notch homolog 1	Homo sapiens	76-79
26553414-0	2015	Phase diagram of the layered oxide SnO: GW and electron-phonon studies.	glycyltryptophan	40-42	strawberry notch homolog 1	Homo sapiens	35-38
26553414-1	2015	First-principles calculations are performed to study the electronic properties and the electron-phonon interactions of the layered oxide semiconductor SnO.	Oxides	131-136	strawberry notch homolog 1	Homo sapiens	151-154
26726376-3	2015	However, our experimental data shows that the width normalized parasitic resistances of SnO TFT with Ni electrodes are around one to three orders of magnitude higher than those in the representative n-type oxide TFT, amorphous indium- gallium-zinc oxide TFT, and are comparable with those in amorphous silicon TFTs with Mo electrodes.	indium- gallium-zinc oxide	227-253	strawberry notch homolog 1	Homo sapiens	88-91
26479808-0	2015	Fiber-optic ammonia sensor using Ag/SnO(2) thin films: optimization of thickness of SnO(2) film using electric field distribution and reaction factor.	Ammonia	12-19	strawberry notch homolog 1	Homo sapiens	36-39
26479808-0	2015	Fiber-optic ammonia sensor using Ag/SnO(2) thin films: optimization of thickness of SnO(2) film using electric field distribution and reaction factor.	Ammonia	12-19	strawberry notch homolog 1	Homo sapiens	84-87
26479808-1	2015	A highly sensitive ammonia gas sensor exploiting the gas sensing characteristics of tin oxide (SnO&lt;sub&gt;2&lt;/sub&gt;) has been reported.	Ammonia	19-26	strawberry notch homolog 1	Homo sapiens	95-98
26479808-1	2015	A highly sensitive ammonia gas sensor exploiting the gas sensing characteristics of tin oxide (SnO&lt;sub&gt;2&lt;/sub&gt;) has been reported.	stannic oxide	84-93	strawberry notch homolog 1	Homo sapiens	95-98
26479808-3	2015	The sensing principle relies on the change in refractive index of SnO&lt;sub&gt;2&lt;/sub&gt; upon its reaction with ammonia gas.	Ammonia	117-124	strawberry notch homolog 1	Homo sapiens	66-69
26479808-5	2015	To enhance the sensitivity, probes with different thicknesses of SnO&lt;sub&gt;2&lt;/sub&gt; have been fabricated and characterized for ammonia sensing.	Ammonia	136-143	strawberry notch homolog 1	Homo sapiens	65-68
26726376-3	2015	However, our experimental data shows that the width normalized parasitic resistances of SnO TFT with Ni electrodes are around one to three orders of magnitude higher than those in the representative n-type oxide TFT, amorphous indium- gallium-zinc oxide TFT, and are comparable with those in amorphous silicon TFTs with Mo electrodes.	Silicon	302-309	strawberry notch homolog 1	Homo sapiens	88-91
26134476-2	2015	Here, we report a mixed metal oxide WO3-SnO2 nanostructured material synthesized in situ by a simple, single-step, one-pot hydrothermal method at 200  C in 12 h, and demonstrate its superior sensing behavior towards volatile organic compounds (VOCs) such as ammonia, ethanol and acetone.	Ammonia	258-265	strawberry notch homolog 1	Homo sapiens	40-43
26189702-4	2015	We report a dielectric layer for passivation of the back-channel surface of 20 nm thick tin monoxide (SnO) TFTs to achieve ambipolar operation and complementary metal oxide semiconductor (CMOS) like logic devices.	Tin(II) oxide	88-100	strawberry notch homolog 1	Homo sapiens	102-105
26189702-4	2015	We report a dielectric layer for passivation of the back-channel surface of 20 nm thick tin monoxide (SnO) TFTs to achieve ambipolar operation and complementary metal oxide semiconductor (CMOS) like logic devices.	metal oxide	161-172	strawberry notch homolog 1	Homo sapiens	102-105
26134476-2	2015	Here, we report a mixed metal oxide WO3-SnO2 nanostructured material synthesized in situ by a simple, single-step, one-pot hydrothermal method at 200  C in 12 h, and demonstrate its superior sensing behavior towards volatile organic compounds (VOCs) such as ammonia, ethanol and acetone.	Ethanol	267-274	strawberry notch homolog 1	Homo sapiens	40-43
26134476-2	2015	Here, we report a mixed metal oxide WO3-SnO2 nanostructured material synthesized in situ by a simple, single-step, one-pot hydrothermal method at 200  C in 12 h, and demonstrate its superior sensing behavior towards volatile organic compounds (VOCs) such as ammonia, ethanol and acetone.	Acetone	279-286	strawberry notch homolog 1	Homo sapiens	40-43
26108919-2	2015	The RGO/SnO2 QD based sensor shows a high response of ~89.3% to H2 and ~92.4% to LPG for 500 ppm test gas concentration at operating temperatures of 200  C and 250  C, respectively.	Hydrogen	64-66	strawberry notch homolog 1	Homo sapiens	8-11
26108919-3	2015	Further, the RGO/SnO2 QD based sensor shows good selectivity for H2 and LPG in the presence of other interfering gases such as ammonia, chloroform, toluene, benzene, acetone, n-butylacetate, acetic acid and formic acid.	Hydrogen	65-67	strawberry notch homolog 1	Homo sapiens	17-20
26108919-3	2015	Further, the RGO/SnO2 QD based sensor shows good selectivity for H2 and LPG in the presence of other interfering gases such as ammonia, chloroform, toluene, benzene, acetone, n-butylacetate, acetic acid and formic acid.	Ammonia	127-134	strawberry notch homolog 1	Homo sapiens	17-20
26108919-3	2015	Further, the RGO/SnO2 QD based sensor shows good selectivity for H2 and LPG in the presence of other interfering gases such as ammonia, chloroform, toluene, benzene, acetone, n-butylacetate, acetic acid and formic acid.	Chloroform	136-146	strawberry notch homolog 1	Homo sapiens	17-20
26108919-3	2015	Further, the RGO/SnO2 QD based sensor shows good selectivity for H2 and LPG in the presence of other interfering gases such as ammonia, chloroform, toluene, benzene, acetone, n-butylacetate, acetic acid and formic acid.	Toluene	148-155	strawberry notch homolog 1	Homo sapiens	17-20
26108919-3	2015	Further, the RGO/SnO2 QD based sensor shows good selectivity for H2 and LPG in the presence of other interfering gases such as ammonia, chloroform, toluene, benzene, acetone, n-butylacetate, acetic acid and formic acid.	Benzene	157-164	strawberry notch homolog 1	Homo sapiens	17-20
26108919-3	2015	Further, the RGO/SnO2 QD based sensor shows good selectivity for H2 and LPG in the presence of other interfering gases such as ammonia, chloroform, toluene, benzene, acetone, n-butylacetate, acetic acid and formic acid.	Acetone	166-173	strawberry notch homolog 1	Homo sapiens	17-20
26108919-3	2015	Further, the RGO/SnO2 QD based sensor shows good selectivity for H2 and LPG in the presence of other interfering gases such as ammonia, chloroform, toluene, benzene, acetone, n-butylacetate, acetic acid and formic acid.	butyl acetate	175-189	strawberry notch homolog 1	Homo sapiens	17-20
26108919-3	2015	Further, the RGO/SnO2 QD based sensor shows good selectivity for H2 and LPG in the presence of other interfering gases such as ammonia, chloroform, toluene, benzene, acetone, n-butylacetate, acetic acid and formic acid.	Acetic Acid	191-202	strawberry notch homolog 1	Homo sapiens	17-20
26108919-3	2015	Further, the RGO/SnO2 QD based sensor shows good selectivity for H2 and LPG in the presence of other interfering gases such as ammonia, chloroform, toluene, benzene, acetone, n-butylacetate, acetic acid and formic acid.	formic acid	207-218	strawberry notch homolog 1	Homo sapiens	17-20
25504364-1	2015	SnO(x) (x = 0, 1, 2) and TiO(2) are widely considered to be potential anode candidates for next generation lithium ion batteries.	Lithium	107-114	strawberry notch homolog 1	Homo sapiens	0-3
26088037-5	2015	We conclude that the double-layer SnO is a promising material for visible-light driven photocatalysts for hydrogen evolution.	Hydrogen	106-114	strawberry notch homolog 1	Homo sapiens	34-37
26095109-2	2015	Depending on the orientation of the -SNO group, two conformers (anti and syn) are identified in the vapor of (CH3 )3 CSNO at room temperature, the syn conformer being less abundant.	(ch3 )3 csno	109-121	strawberry notch homolog 1	Homo sapiens	37-40
25990302-0	2015	Understanding the role of the dye/oxide interface via SnO2-based MK-2 dye-sensitized solar cells.	Oxides	34-39	strawberry notch homolog 1	Homo sapiens	54-57
25747103-0	2015	Terbium doped SnO2 nanoparticles as white emitters and SnO2:5Tb/Fe3O4 magnetic luminescent nanohybrids for hyperthermia application and biocompatibility with HeLa cancer cells.	Terbium	0-7	strawberry notch homolog 1	Homo sapiens	14-17
25504364-5	2015	This Review aims to provide rational understanding on their design and the improvement of electrochemical properties of such systems, including SnO(x) -TiO(2) nanocomposites mixing at nanoscale and nanostructured Sn(x) Ti(1-x) O(2) solid solutions doped at the atomic level, as well as their combinations with carbon-based nanomaterials.	Acetaminophen	148-150	strawberry notch homolog 1	Homo sapiens	144-147
24598127-1	2014	Unique SnO(x) (x = 1,2)/ordered mesoporous carbon nanocomposites (denoted as SnO(x)/OMC) are firstly synthesized through a "one-pot" synthesis together with the soft template self-assembly approach.	Carbon	43-49	strawberry notch homolog 1	Homo sapiens	77-80
25692741-4	2015	The most common method to assay biological S-nitroso compounds is to chemically or photochemically reduce SNO functional groups to release nitric oxide, which is then entrained in an inert gas stream and detected, usually through chemiluminescence.	Nitroso Compounds	43-62	strawberry notch homolog 1	Homo sapiens	106-109
25692741-4	2015	The most common method to assay biological S-nitroso compounds is to chemically or photochemically reduce SNO functional groups to release nitric oxide, which is then entrained in an inert gas stream and detected, usually through chemiluminescence.	Nitric Oxide	139-151	strawberry notch homolog 1	Homo sapiens	106-109
25389036-0	2015	Cyanogel-derived formation of 3 D nanoporous SnO2-MxOy (M=Ni, Fe, Co) hybrid networks for high-performance lithium storage.	cyanogel	0-8	strawberry notch homolog 1	Homo sapiens	45-48
25389036-0	2015	Cyanogel-derived formation of 3 D nanoporous SnO2-MxOy (M=Ni, Fe, Co) hybrid networks for high-performance lithium storage.	Lithium	107-114	strawberry notch homolog 1	Homo sapiens	45-48
25347762-4	2014	The porous SnO2-Fe2O3 nanocubes as anode materials for the lithium-ion battery show a high initial capacity of 1020.2 mA h g(-1) at a current density of 200 mA g(-1) and maintain at 567.5 mA h g(-1) at the 50th cycle, which is distinctly higher than those reported for SnO2-based materials.	Iron(III) oxide	16-21	strawberry notch homolog 1	Homo sapiens	11-14
25347762-4	2014	The porous SnO2-Fe2O3 nanocubes as anode materials for the lithium-ion battery show a high initial capacity of 1020.2 mA h g(-1) at a current density of 200 mA g(-1) and maintain at 567.5 mA h g(-1) at the 50th cycle, which is distinctly higher than those reported for SnO2-based materials.	Lithium	59-66	strawberry notch homolog 1	Homo sapiens	11-14
25443875-3	2014	We hypothesised that thienopyridines expose the free thiol group once acidified (by the stomach) before biotransformation into active metabolites, and in the presence of nitrite (from saliva and the stomach) to form nitrosothiol derivatives (Thienopyridine induced-SNO formation).	Thienopyridines	21-36	strawberry notch homolog 1	Homo sapiens	265-268
25443875-3	2014	We hypothesised that thienopyridines expose the free thiol group once acidified (by the stomach) before biotransformation into active metabolites, and in the presence of nitrite (from saliva and the stomach) to form nitrosothiol derivatives (Thienopyridine induced-SNO formation).	Sulfhydryl Compounds	53-58	strawberry notch homolog 1	Homo sapiens	265-268
25443875-3	2014	We hypothesised that thienopyridines expose the free thiol group once acidified (by the stomach) before biotransformation into active metabolites, and in the presence of nitrite (from saliva and the stomach) to form nitrosothiol derivatives (Thienopyridine induced-SNO formation).	S-Nitrosothiols	216-228	strawberry notch homolog 1	Homo sapiens	265-268
25443875-4	2014	We have performed in vitro studies with each of the thienopyridines tablets/compounds confirming direct Th-SNO formation from the parent (inactive) drug by the following mechanism.	Thienopyridines	52-67	strawberry notch homolog 1	Homo sapiens	107-110
25443875-5	2014	Thienopyridine-SH + H(+ (Stomach)) +  [Formula: see text]   Thienopyridine-SNO + H2O Thienopyridine-SNO (an S-nitrosothiol molecule) would have the potential to participate in all the reactions expected of native nitric oxide (NO) with added benefit that the NO "moiety" is protected, transportable and largely preserved from further reactive metabolism.	thienopyridine	0-14	strawberry notch homolog 1	Homo sapiens	75-78
25443875-5	2014	Thienopyridine-SH + H(+ (Stomach)) +  [Formula: see text]   Thienopyridine-SNO + H2O Thienopyridine-SNO (an S-nitrosothiol molecule) would have the potential to participate in all the reactions expected of native nitric oxide (NO) with added benefit that the NO "moiety" is protected, transportable and largely preserved from further reactive metabolism.	thienopyridine	0-14	strawberry notch homolog 1	Homo sapiens	100-103
25443875-5	2014	Thienopyridine-SH + H(+ (Stomach)) +  [Formula: see text]   Thienopyridine-SNO + H2O Thienopyridine-SNO (an S-nitrosothiol molecule) would have the potential to participate in all the reactions expected of native nitric oxide (NO) with added benefit that the NO "moiety" is protected, transportable and largely preserved from further reactive metabolism.	thienopyridine	60-74	strawberry notch homolog 1	Homo sapiens	75-78
25443875-5	2014	Thienopyridine-SH + H(+ (Stomach)) +  [Formula: see text]   Thienopyridine-SNO + H2O Thienopyridine-SNO (an S-nitrosothiol molecule) would have the potential to participate in all the reactions expected of native nitric oxide (NO) with added benefit that the NO "moiety" is protected, transportable and largely preserved from further reactive metabolism.	thienopyridine	60-74	strawberry notch homolog 1	Homo sapiens	100-103
25443875-5	2014	Thienopyridine-SH + H(+ (Stomach)) +  [Formula: see text]   Thienopyridine-SNO + H2O Thienopyridine-SNO (an S-nitrosothiol molecule) would have the potential to participate in all the reactions expected of native nitric oxide (NO) with added benefit that the NO "moiety" is protected, transportable and largely preserved from further reactive metabolism.	Water	81-84	strawberry notch homolog 1	Homo sapiens	75-78
25443875-5	2014	Thienopyridine-SH + H(+ (Stomach)) +  [Formula: see text]   Thienopyridine-SNO + H2O Thienopyridine-SNO (an S-nitrosothiol molecule) would have the potential to participate in all the reactions expected of native nitric oxide (NO) with added benefit that the NO "moiety" is protected, transportable and largely preserved from further reactive metabolism.	Water	81-84	strawberry notch homolog 1	Homo sapiens	100-103
25443875-5	2014	Thienopyridine-SH + H(+ (Stomach)) +  [Formula: see text]   Thienopyridine-SNO + H2O Thienopyridine-SNO (an S-nitrosothiol molecule) would have the potential to participate in all the reactions expected of native nitric oxide (NO) with added benefit that the NO "moiety" is protected, transportable and largely preserved from further reactive metabolism.	thienopyridine	60-74	strawberry notch homolog 1	Homo sapiens	75-78
25443875-5	2014	Thienopyridine-SH + H(+ (Stomach)) +  [Formula: see text]   Thienopyridine-SNO + H2O Thienopyridine-SNO (an S-nitrosothiol molecule) would have the potential to participate in all the reactions expected of native nitric oxide (NO) with added benefit that the NO "moiety" is protected, transportable and largely preserved from further reactive metabolism.	thienopyridine	60-74	strawberry notch homolog 1	Homo sapiens	100-103
25443875-5	2014	Thienopyridine-SH + H(+ (Stomach)) +  [Formula: see text]   Thienopyridine-SNO + H2O Thienopyridine-SNO (an S-nitrosothiol molecule) would have the potential to participate in all the reactions expected of native nitric oxide (NO) with added benefit that the NO "moiety" is protected, transportable and largely preserved from further reactive metabolism.	S-Nitrosothiols	108-122	strawberry notch homolog 1	Homo sapiens	75-78
25443875-5	2014	Thienopyridine-SH + H(+ (Stomach)) +  [Formula: see text]   Thienopyridine-SNO + H2O Thienopyridine-SNO (an S-nitrosothiol molecule) would have the potential to participate in all the reactions expected of native nitric oxide (NO) with added benefit that the NO "moiety" is protected, transportable and largely preserved from further reactive metabolism.	S-Nitrosothiols	108-122	strawberry notch homolog 1	Homo sapiens	100-103
25443875-5	2014	Thienopyridine-SH + H(+ (Stomach)) +  [Formula: see text]   Thienopyridine-SNO + H2O Thienopyridine-SNO (an S-nitrosothiol molecule) would have the potential to participate in all the reactions expected of native nitric oxide (NO) with added benefit that the NO "moiety" is protected, transportable and largely preserved from further reactive metabolism.	Nitric Oxide	213-225	strawberry notch homolog 1	Homo sapiens	75-78
25443875-5	2014	Thienopyridine-SH + H(+ (Stomach)) +  [Formula: see text]   Thienopyridine-SNO + H2O Thienopyridine-SNO (an S-nitrosothiol molecule) would have the potential to participate in all the reactions expected of native nitric oxide (NO) with added benefit that the NO "moiety" is protected, transportable and largely preserved from further reactive metabolism.	Nitric Oxide	213-225	strawberry notch homolog 1	Homo sapiens	100-103
25034037-0	2014	Incorporation of heterostructured Sn/SnO nanoparticles in crumpled nitrogen-doped graphene nanosheets for application as anodes in lithium-ion batteries.	Nitrogen	67-75	strawberry notch homolog 1	Homo sapiens	37-40
25034037-0	2014	Incorporation of heterostructured Sn/SnO nanoparticles in crumpled nitrogen-doped graphene nanosheets for application as anodes in lithium-ion batteries.	Graphite	82-90	strawberry notch homolog 1	Homo sapiens	37-40
25034037-0	2014	Incorporation of heterostructured Sn/SnO nanoparticles in crumpled nitrogen-doped graphene nanosheets for application as anodes in lithium-ion batteries.	Lithium	131-138	strawberry notch homolog 1	Homo sapiens	37-40
25034037-1	2014	Sn/SnO nanoparticles are incorporated in crumpled nitrogen-doped graphene nanosheets by a simple melting diffusion method.	Tin	0-2	strawberry notch homolog 1	Homo sapiens	3-6
25034037-1	2014	Sn/SnO nanoparticles are incorporated in crumpled nitrogen-doped graphene nanosheets by a simple melting diffusion method.	Nitrogen	50-58	strawberry notch homolog 1	Homo sapiens	3-6
25034037-1	2014	Sn/SnO nanoparticles are incorporated in crumpled nitrogen-doped graphene nanosheets by a simple melting diffusion method.	Graphite	65-73	strawberry notch homolog 1	Homo sapiens	3-6
24912617-0	2014	Polymer ferroelectric field-effect memory device with SnO channel layer exhibits record hole mobility.	Polymers	0-7	strawberry notch homolog 1	Homo sapiens	54-57
25410593-1	2014	We suggest that the lithiation of pristine SnO forms a layered LiXO structure, while the expelled tin atoms agglomerate into "surface" planes separating the LiXO layers.	Tin	38-41	strawberry notch homolog 1	Homo sapiens	43-46
25410593-3	2014	With this model, we are able to account for the various tin bonds that are seen experimentally and explain the three volume expansion phases that occur when SnO undergoes lithiation: (i) at low concentrations Li behaves as an intercalated species inducing small volume increases; (ii) for intermediate concentrations SnO transforms into lithia causing a large expansion; and (iii) finally, as the Li concentration further increases a saturation of the lithia takes place until a layered Li2O is formed.	Dilithium oxide	487-491	strawberry notch homolog 1	Homo sapiens	157-160
25415540-0	2014	Electrochemical oxidation of hydrolyzed poly oxymethylene-dimethyl ether by PtRu catalysts on Nb-doped SnO(2-delta) supports for direct oxidation fuel cells.	poly oxymethylene-dimethyl ether	40-72	strawberry notch homolog 1	Homo sapiens	103-106
26055937-0	2014	Characterization of SnO2-based (68)Ge/ (68)Ga generators and (68)Ga-DOTATATE preparations: radionuclide purity, radiochemical yield and long-term constancy.	Gallium	43-45	strawberry notch homolog 1	Homo sapiens	20-23
24986430-2	2014	S-Nitrosated bovine serum albumin and the S-nitrosated C-terminally truncated form of AdhR-SH (alcohol dehydrogenase regulator) designated as AdhR*-SNO were selectively labelled by the thiosulfonate switch both individually and in protein mixtures containing free thiols.	thiosulfonate	185-198	strawberry notch homolog 1	Homo sapiens	148-151
24986430-2	2014	S-Nitrosated bovine serum albumin and the S-nitrosated C-terminally truncated form of AdhR-SH (alcohol dehydrogenase regulator) designated as AdhR*-SNO were selectively labelled by the thiosulfonate switch both individually and in protein mixtures containing free thiols.	Sulfhydryl Compounds	264-270	strawberry notch homolog 1	Homo sapiens	148-151
25201412-6	2014	Rescue by TRXh5 was conferred through selective denitrosylation of excessive protein-SNO, which reinstated signaling by the immune hormone salicylic acid.	Salicylic Acid	139-153	strawberry notch homolog 1	Homo sapiens	85-88
25036847-1	2014	In this work, we had investigated sputtering deposition of p-type SnO using the widely used and robust SnO2 target in a hydrogen-containing reducing atmosphere.	Hydrogen	120-128	strawberry notch homolog 1	Homo sapiens	66-69
25036847-3	2014	Results show that polycrystalline and SnO-dominant films could be readily obtained by carefully controlling the hydrogen gas ratio in the sputtering gas and the extent of reduction reaction.	Hydrogen	112-120	strawberry notch homolog 1	Homo sapiens	38-41
24830634-0	2014	Ternary Pt/SnO(x)/TiO2 photocatalysts for hydrogen production: consequence of Pt sites for synergy of dual co-catalysts.	Hydrogen	42-50	strawberry notch homolog 1	Homo sapiens	11-14
24643582-0	2014	Heterostructured ZnO/SnO(2-x) nanoparticles for efficient photocatalytic hydrogen production.	Hydrogen	73-81	strawberry notch homolog 1	Homo sapiens	21-24
24643582-1	2014	Heterostructured ZnO/SnO(2-x) nanoparticles (NPs) were synthesized by a facile two-step hydrothermal process for the first time and exhibited excellent photocatalytic activity due to increased oxygen vacancies and matched band edge alignment.	Oxygen	193-199	strawberry notch homolog 1	Homo sapiens	21-24
24522961-0	2014	Hierarchical mesoporous SnO microspheres as high capacity anode materials for sodium-ion batteries.	Sodium	78-84	strawberry notch homolog 1	Homo sapiens	24-27
24522961-1	2014	Mesoporous SnO microspheres were synthesised by a hydrothermal method using NaSO4 as the morphology directing agent.	naso4	76-81	strawberry notch homolog 1	Homo sapiens	11-14
24522961-4	2014	When applied as anode materials in Na-ion batteries, SnO microspheres exhibited high reversible sodium storage capacity, good cyclability and a satisfactory high rate performance.	Sodium	96-102	strawberry notch homolog 1	Homo sapiens	53-56
24522961-7	2014	The high sodium storage capacity and good electrochemical performance could be ascribed to the unique hierarchical mesoporous architecture of SnO microspheres.	Sodium	9-15	strawberry notch homolog 1	Homo sapiens	142-145
24393850-9	2014	Finally, we showed that SNO decreased the internalization rate of F508del CFTR in HBAE cells.	f508del	66-73	strawberry notch homolog 1	Homo sapiens	24-27
32261347-0	2014	Template-free synthesis of uniform mesoporous SnO2 nanospheres for efficient phosphopeptide enrichment.	Phosphopeptides	77-91	strawberry notch homolog 1	Homo sapiens	46-49
24462893-7	2014	The accelerated service life of Ti/Sb-SnO(2)/Pb(3)O(4) electrode could reach 180 h at a current density of 10,000 A m(-2) in 0.5 molL(-1) H(2)SO(4).	Titanium	32-34	strawberry notch homolog 1	Homo sapiens	38-41
23963262-1	2013	An easily synthesised Sn(II) bis(ureide) derivative is shown to be a single-source precursor for the aerosol-assisted CVD of SnO, providing unprecedented levels of oxidation state control at temperatures as low as 250  C.	sn(ii) bis(ureide)	22-40	strawberry notch homolog 1	Homo sapiens	125-128
24671400-7	2014	However, their indirect determination by means of H2O2 measurements revealed that Ti/IrO2-SnO2-Sb2O5 is able to produce partially physisorbed radicals.	Hydrogen Peroxide	50-54	strawberry notch homolog 1	Homo sapiens	90-93
23668750-5	2013	Specifically, we show that phase-pure SnO is not necessarily the highest mobility phase; instead, well-controlled amounts of residual metallic tin are shown to substantially increase the hole mobility.	Tin	134-146	strawberry notch homolog 1	Homo sapiens	38-41
23900070-2	2013	The SnO intermediate, which was produced in the reactions between epoxide and [Sn(H2O)6](2+), was converted to SnO2 quantum dots by the oxidation of H2O2.	Epoxy Compounds	66-73	strawberry notch homolog 1	Homo sapiens	4-7
23900070-2	2013	The SnO intermediate, which was produced in the reactions between epoxide and [Sn(H2O)6](2+), was converted to SnO2 quantum dots by the oxidation of H2O2.	sn(h2o)6	79-87	strawberry notch homolog 1	Homo sapiens	4-7
23900070-2	2013	The SnO intermediate, which was produced in the reactions between epoxide and [Sn(H2O)6](2+), was converted to SnO2 quantum dots by the oxidation of H2O2.	Tin(IV) oxide	111-115	strawberry notch homolog 1	Homo sapiens	4-7
23900070-2	2013	The SnO intermediate, which was produced in the reactions between epoxide and [Sn(H2O)6](2+), was converted to SnO2 quantum dots by the oxidation of H2O2.	Hydrogen Peroxide	149-153	strawberry notch homolog 1	Homo sapiens	4-7
23743421-2	2013	This study noted by 4,5-diaminofluorescein diacetate (DAF-2DA) staining and confocal laser scanning microscopy (CLSM) the presence of nitrososulfides (SNO) complex in the S(2-)+NO-amended methanogenic sludge.	4,5-diaminofluorescein diacetate	20-52	strawberry notch homolog 1	Homo sapiens	151-154
23743421-2	2013	This study noted by 4,5-diaminofluorescein diacetate (DAF-2DA) staining and confocal laser scanning microscopy (CLSM) the presence of nitrososulfides (SNO) complex in the S(2-)+NO-amended methanogenic sludge.	nitrososulfides	134-149	strawberry notch homolog 1	Homo sapiens	151-154
23743421-3	2013	Kinetic analysis suggested two-step kinetics involving chemical equilibrium between S(2-), NO and SNO as step 1 and the slow conversion from SNO to N2O as step 2.	Nitrous Oxide	148-151	strawberry notch homolog 1	Homo sapiens	98-101
23743421-3	2013	Kinetic analysis suggested two-step kinetics involving chemical equilibrium between S(2-), NO and SNO as step 1 and the slow conversion from SNO to N2O as step 2.	Nitrous Oxide	148-151	strawberry notch homolog 1	Homo sapiens	141-144
23743421-5	2013	Comments were made on the role of SNO complex for the interactions between sulfur, nitrogen and carbon metabolisms in anaerobic digestion.	Sulfur	75-81	strawberry notch homolog 1	Homo sapiens	34-37
23743421-5	2013	Comments were made on the role of SNO complex for the interactions between sulfur, nitrogen and carbon metabolisms in anaerobic digestion.	Nitrogen	83-91	strawberry notch homolog 1	Homo sapiens	34-37
23743421-5	2013	Comments were made on the role of SNO complex for the interactions between sulfur, nitrogen and carbon metabolisms in anaerobic digestion.	Carbon	96-102	strawberry notch homolog 1	Homo sapiens	34-37
23553289-3	2013	However, the (3+2) cycloaddition reaction barriers can be dramatically lowered by coordination of a Lewis acid to the N atom of the -SNO group.	Lewis Acids	100-110	strawberry notch homolog 1	Homo sapiens	133-136
23553289-3	2013	However, the (3+2) cycloaddition reaction barriers can be dramatically lowered by coordination of a Lewis acid to the N atom of the -SNO group.	Nitrogen	118-119	strawberry notch homolog 1	Homo sapiens	133-136
23668750-6	2013	A detailed phase stability map for physical vapor deposition of nanoscale SnO is constructed for the first time for this p-type oxide.	Oxides	128-133	strawberry notch homolog 1	Homo sapiens	74-77
23553828-0	2013	Hierarchical tubular structures constructed by carbon-coated SnO(2) nanoplates for highly reversible lithium storage.	Carbon	47-53	strawberry notch homolog 1	Homo sapiens	61-64
23670638-0	2013	Carbon and graphene double protection strategy to improve the SnO(x) electrode performance anodes for lithium-ion batteries.	Carbon	0-6	strawberry notch homolog 1	Homo sapiens	62-65
23670638-0	2013	Carbon and graphene double protection strategy to improve the SnO(x) electrode performance anodes for lithium-ion batteries.	Graphite	11-19	strawberry notch homolog 1	Homo sapiens	62-65
23670638-0	2013	Carbon and graphene double protection strategy to improve the SnO(x) electrode performance anodes for lithium-ion batteries.	Lithium	102-109	strawberry notch homolog 1	Homo sapiens	62-65
23614769-6	2013	We further show that a triarylphosphine-thiophenyl ester can be used in the absolute quantification of endogenous GSNO in several cancer cell lines, while retaining the elements of the SNO functional group, using an LC-MS-based assay.	triarylphosphine-thiophenyl ester	23-56	strawberry notch homolog 1	Homo sapiens	115-118
23553828-0	2013	Hierarchical tubular structures constructed by carbon-coated SnO(2) nanoplates for highly reversible lithium storage.	Lithium	101-108	strawberry notch homolog 1	Homo sapiens	61-64
23553828-1	2013	Hierarchical tubular structures constructed by ultrathin carbon-coated SnO(2) nanoplates are rationally designed and synthesized.	Carbon	57-63	strawberry notch homolog 1	Homo sapiens	71-74
23553828-3	2013	When evaluated as an anode material for lithium-ion batteries, the as-synthesized SnO(2)-carbon hybrid structure manifests high specific capacity and excellent cycling stability.	Lithium	40-47	strawberry notch homolog 1	Homo sapiens	82-85
23553828-3	2013	When evaluated as an anode material for lithium-ion batteries, the as-synthesized SnO(2)-carbon hybrid structure manifests high specific capacity and excellent cycling stability.	Carbon	89-95	strawberry notch homolog 1	Homo sapiens	82-85
23232981-1	2013	Here we demonstrate a facile method of quantifying the decaying optical field surrounding free-standing tin dioxide (SnO(2)) nanofiber waveguides.	stannic oxide	104-115	strawberry notch homolog 1	Homo sapiens	117-120
23519347-0	2013	Improvement of H2S sensing properties of SnO2-based thick film gas sensors promoted with MoO3 and NiO.	Hydrogen Sulfide	15-18	strawberry notch homolog 1	Homo sapiens	41-44
23519347-0	2013	Improvement of H2S sensing properties of SnO2-based thick film gas sensors promoted with MoO3 and NiO.	molybdenum trioxide	89-93	strawberry notch homolog 1	Homo sapiens	41-44
23519347-0	2013	Improvement of H2S sensing properties of SnO2-based thick film gas sensors promoted with MoO3 and NiO.	nio	98-101	strawberry notch homolog 1	Homo sapiens	41-44
23519347-3	2013	The SnO2 materials were prepared by calcining SnO2 at 600, 800, 1,000 and 1,200  C to give materials identified as SnO2(600), SnO2(800), SnO2(1000), and SnO2(1200), respectively.	Tin(IV) oxide	4-8	strawberry notch homolog 1	Homo sapiens	46-49
23519347-3	2013	The SnO2 materials were prepared by calcining SnO2 at 600, 800, 1,000 and 1,200  C to give materials identified as SnO2(600), SnO2(800), SnO2(1000), and SnO2(1200), respectively.	Tin(IV) oxide	46-50	strawberry notch homolog 1	Homo sapiens	4-7
23519347-3	2013	The SnO2 materials were prepared by calcining SnO2 at 600, 800, 1,000 and 1,200  C to give materials identified as SnO2(600), SnO2(800), SnO2(1000), and SnO2(1200), respectively.	Tin(IV) oxide	46-50	strawberry notch homolog 1	Homo sapiens	4-7
23519347-3	2013	The SnO2 materials were prepared by calcining SnO2 at 600, 800, 1,000 and 1,200  C to give materials identified as SnO2(600), SnO2(800), SnO2(1000), and SnO2(1200), respectively.	Tin(IV) oxide	46-50	strawberry notch homolog 1	Homo sapiens	4-7
23514500-13	2013	These new results allow for the reassignment of earlier experimental IR bands of SNO trapped in cooled argon matrices.	Argon	103-108	strawberry notch homolog 1	Homo sapiens	81-84
23382182-4	2013	Here we report that in neurons and brain tissue NO can S-nitrosylate SHP-2 at its active site cysteine, forming S-nitrosylated SHP-2 (SNO-SHP-2).	Cysteine	94-102	strawberry notch homolog 1	Homo sapiens	134-137
23382182-5	2013	We found that NMDA exposure in vitro and transient focal cerebral ischemia in vivo resulted in increased levels of SNO-SHP-2.	N-Methylaspartate	14-18	strawberry notch homolog 1	Homo sapiens	115-118
23479738-4	2013	We found that, both in a cell-free system and in cells, NO/SNO donors such as S-nitrosocysteine and S-nitrosoglutathione readily induced the S-nitrosylation of Prx1, causing structural and functional alterations.	S-nitrosocysteine	78-95	strawberry notch homolog 1	Homo sapiens	59-62
23479738-4	2013	We found that, both in a cell-free system and in cells, NO/SNO donors such as S-nitrosocysteine and S-nitrosoglutathione readily induced the S-nitrosylation of Prx1, causing structural and functional alterations.	S-Nitrosoglutathione	100-120	strawberry notch homolog 1	Homo sapiens	59-62
23270418-2	2013	Sn was employed as the In(2)O(3) dopant to exploit the strong interaction between Sn and Pt that was previously reported to enhance the activity of Pt on Pt/SnO(2), while concomitantly avoiding the intrinsic stability limitations of SnO(2) and leveraging the high stability of bulk In(2)O(3) at ORR relevant potentials.	Tin	0-2	strawberry notch homolog 1	Homo sapiens	157-160
23270418-2	2013	Sn was employed as the In(2)O(3) dopant to exploit the strong interaction between Sn and Pt that was previously reported to enhance the activity of Pt on Pt/SnO(2), while concomitantly avoiding the intrinsic stability limitations of SnO(2) and leveraging the high stability of bulk In(2)O(3) at ORR relevant potentials.	Tin	0-2	strawberry notch homolog 1	Homo sapiens	233-236
23281416-3	2013	From this perspective, SNO-based signaling may have evolved as a major transducer of the cellular oxygen-sensing machinery that underlies global cardiovascular function.	Oxygen	98-104	strawberry notch homolog 1	Homo sapiens	23-26
23259819-1	2013	As advanced electrodes for direct alcohol fuel cells, graphene-Pd and graphene-Pt composites with a trace of SnO(2) have been successfully synthesized by a modified electroless plating technique.	Graphite	54-62	strawberry notch homolog 1	Homo sapiens	109-112
23259819-1	2013	As advanced electrodes for direct alcohol fuel cells, graphene-Pd and graphene-Pt composites with a trace of SnO(2) have been successfully synthesized by a modified electroless plating technique.	Graphite	70-78	strawberry notch homolog 1	Homo sapiens	109-112
23259819-1	2013	As advanced electrodes for direct alcohol fuel cells, graphene-Pd and graphene-Pt composites with a trace of SnO(2) have been successfully synthesized by a modified electroless plating technique.	Platinum	79-81	strawberry notch homolog 1	Homo sapiens	109-112
23210450-7	2013	We demonstrate that the PtIr/SnO(2)/C catalyst with high Ir content shows outstanding catalytic properties with the most negative EOR onset potential and reasonably good selectivity toward ethanol complete oxidation to CO(2).	Ethanol	189-196	strawberry notch homolog 1	Homo sapiens	29-32
23210450-7	2013	We demonstrate that the PtIr/SnO(2)/C catalyst with high Ir content shows outstanding catalytic properties with the most negative EOR onset potential and reasonably good selectivity toward ethanol complete oxidation to CO(2).	Carbon Dioxide	219-224	strawberry notch homolog 1	Homo sapiens	29-32
23160279-3	2012	204) with the unit-cell parameter a = 7.64535(6) A at 300 K. The SnO(6) network is extremely tilted, giving rise to a square planar coordination for Cu(2+) cations.	Copper	149-151	strawberry notch homolog 1	Homo sapiens	65-68
22893615-1	2012	The humidity sensitivity of a single beta-Ga(2) O(3) /amorphous SnO(2)  core/shell microribbon on a flexible substrate is enhanced by the application of tensile strain and increases linearly with the strain.	beta-ga	37-44	strawberry notch homolog 1	Homo sapiens	64-67
23378867-0	2012	Particle Networks from Powder Mixtures: Generation of TiO(2)-SnO(2) Heterojunctions via Surface Charge-Induced Heteroaggregation.	titanium dioxide	54-60	strawberry notch homolog 1	Homo sapiens	61-64
23076806-1	2012	Undoped nanostructured tin oxide (SnO(2)) arrays were prepared on oxidized Si substrates by nanosecond pulsed laser interference irradiation for hydrogen gas sensing applications.	stannic oxide	23-32	strawberry notch homolog 1	Homo sapiens	34-37
23076806-1	2012	Undoped nanostructured tin oxide (SnO(2)) arrays were prepared on oxidized Si substrates by nanosecond pulsed laser interference irradiation for hydrogen gas sensing applications.	Silicon	75-77	strawberry notch homolog 1	Homo sapiens	34-37
23076806-1	2012	Undoped nanostructured tin oxide (SnO(2)) arrays were prepared on oxidized Si substrates by nanosecond pulsed laser interference irradiation for hydrogen gas sensing applications.	Hydrogen	145-153	strawberry notch homolog 1	Homo sapiens	34-37
23076806-4	2012	The observed electrical response of SnO(2) towards hydrogen at low concentrations and room temperature drastically improved in the nanostructured array as compared to the thin film.	Hydrogen	51-59	strawberry notch homolog 1	Homo sapiens	36-39
23076806-5	2012	The results suggest that this method to fabricate SnO(2) nanostructured arrays has the potential to produce nanodevices that have ultra-low detection limits, and fast response and recovery times, which are suited for practical hydrogen sensing applications.	Hydrogen	227-235	strawberry notch homolog 1	Homo sapiens	50-53
22983398-0	2012	Highly electrically conductive layered carbon derived from polydopamine and its functions in SnO2-based lithium ion battery anodes.	Carbon	39-45	strawberry notch homolog 1	Homo sapiens	93-96
22902583-1	2012	Nanocrystalline, tin(IV) oxide (SnO(2)) particles has been prepared by thermal decomposition of tin oxalate precursor obtained from the reactions of tin(IV) chloride and sodium oxalate using eggshell membrane (ESM).	nanocrystalline	0-15	strawberry notch homolog 1	Homo sapiens	32-35
22902583-1	2012	Nanocrystalline, tin(IV) oxide (SnO(2)) particles has been prepared by thermal decomposition of tin oxalate precursor obtained from the reactions of tin(IV) chloride and sodium oxalate using eggshell membrane (ESM).	stannic oxide	17-30	strawberry notch homolog 1	Homo sapiens	32-35
22770619-3	2012	Large spherical Sn nanoparticles with sizes of 20-200nm grew instantaneously upon lithiation of a single-crystalline SnO(2) nanowire at large current density (j&gt;20A/cm(2)), which suppressed formation of the Li(x)Sn alloy but promoted agglomeration of Sn atoms.	Tin	16-18	strawberry notch homolog 1	Homo sapiens	117-120
22770619-4	2012	Control experiments of Joule-heating (j 2400A/cm(2)) the pristine SnO(2) nanowires resulted in melting of the SnO(2) nanowires but not Sn particle growth, indicating that the abnormal Sn particle growth was induced by both chemical reduction (i.e., breaking the SnO(2) lattice to produce Sn atoms) and agglomeration of the Sn atoms assisted by Joule heating.	Tin	66-68	strawberry notch homolog 1	Homo sapiens	110-113
22770619-4	2012	Control experiments of Joule-heating (j 2400A/cm(2)) the pristine SnO(2) nanowires resulted in melting of the SnO(2) nanowires but not Sn particle growth, indicating that the abnormal Sn particle growth was induced by both chemical reduction (i.e., breaking the SnO(2) lattice to produce Sn atoms) and agglomeration of the Sn atoms assisted by Joule heating.	Tin	66-68	strawberry notch homolog 1	Homo sapiens	110-113
23023805-1	2012	There"s something in the air ... A nanocomposite consisting of well-dispersed SnO(2) and Pt nanoparticles on reduced graphene oxide (see the high-resolution TEM image) exhibited very high responses to hydrogen at concentrations between 0.5 and 3% in air, with response times of 3-7 s and recovery times of 2-6 s. The sensor was prepared by a straightforward microwave-assisted non-aqueous sol-gel approach.	graphene oxide	117-131	strawberry notch homolog 1	Homo sapiens	78-81
23023805-1	2012	There"s something in the air ... A nanocomposite consisting of well-dispersed SnO(2) and Pt nanoparticles on reduced graphene oxide (see the high-resolution TEM image) exhibited very high responses to hydrogen at concentrations between 0.5 and 3% in air, with response times of 3-7 s and recovery times of 2-6 s. The sensor was prepared by a straightforward microwave-assisted non-aqueous sol-gel approach.	Hydrogen	201-209	strawberry notch homolog 1	Homo sapiens	78-81
22902583-1	2012	Nanocrystalline, tin(IV) oxide (SnO(2)) particles has been prepared by thermal decomposition of tin oxalate precursor obtained from the reactions of tin(IV) chloride and sodium oxalate using eggshell membrane (ESM).	Tin(II) oxalate	96-107	strawberry notch homolog 1	Homo sapiens	32-35
22983398-0	2012	Highly electrically conductive layered carbon derived from polydopamine and its functions in SnO2-based lithium ion battery anodes.	polydopamine	59-71	strawberry notch homolog 1	Homo sapiens	93-96
22983398-0	2012	Highly electrically conductive layered carbon derived from polydopamine and its functions in SnO2-based lithium ion battery anodes.	Lithium	104-111	strawberry notch homolog 1	Homo sapiens	93-96
22902583-1	2012	Nanocrystalline, tin(IV) oxide (SnO(2)) particles has been prepared by thermal decomposition of tin oxalate precursor obtained from the reactions of tin(IV) chloride and sodium oxalate using eggshell membrane (ESM).	stannic chloride	149-165	strawberry notch homolog 1	Homo sapiens	32-35
22983398-2	2012	Greatly enhanced electrochemical properties are achieved with C-PDA-coated SnO(2) nanoparticles where the coating functions as a mechanical buffer layer and conducting bridge.	c-pda	62-67	strawberry notch homolog 1	Homo sapiens	75-78
22902583-1	2012	Nanocrystalline, tin(IV) oxide (SnO(2)) particles has been prepared by thermal decomposition of tin oxalate precursor obtained from the reactions of tin(IV) chloride and sodium oxalate using eggshell membrane (ESM).	Oxalic Acid	170-184	strawberry notch homolog 1	Homo sapiens	32-35
22902583-2	2012	The as-prepared SnO(2) nanoparticles were characterized by thermal studies, transmission electron microscopy (TEM), powder X-ray diffraction (XRD), Raman, FT-IR and UV-visible studies and used as a photocatalyst for the degradation of rhodamine-B (Rh-B) dye.	rhodamine B	235-246	strawberry notch homolog 1	Homo sapiens	16-19
22902583-2	2012	The as-prepared SnO(2) nanoparticles were characterized by thermal studies, transmission electron microscopy (TEM), powder X-ray diffraction (XRD), Raman, FT-IR and UV-visible studies and used as a photocatalyst for the degradation of rhodamine-B (Rh-B) dye.	rhodamine B	248-252	strawberry notch homolog 1	Homo sapiens	16-19
22422051-2	2012	Herein, we report a large-scale synthesis of a SnO(2)/alpha-Fe(2)O(3) composite nanotube array on a stainless steel substrate via a ZnO nanowire array as an in situ sacrificial template without using any strong acid or alkali.	alpha-fe(2)o(	54-67	strawberry notch homolog 1	Homo sapiens	47-50
22902583-5	2012	Thermal analysis showed that the decomposition of tin oxalate precursor to yield the titled tin(IV) oxide nanoparticles was completed below 500 C. The extent of degradation of Rh-B in the presence of SnO(2) monitored by absorption spectral measurements demonstrated that 94.48% of the selected dye was degraded upon irradiation with UV light for 60 min.	Tin(II) oxalate	50-61	strawberry notch homolog 1	Homo sapiens	200-203
22902583-5	2012	Thermal analysis showed that the decomposition of tin oxalate precursor to yield the titled tin(IV) oxide nanoparticles was completed below 500 C. The extent of degradation of Rh-B in the presence of SnO(2) monitored by absorption spectral measurements demonstrated that 94.48% of the selected dye was degraded upon irradiation with UV light for 60 min.	stannic oxide	92-105	strawberry notch homolog 1	Homo sapiens	200-203
22705913-6	2012	NAC-SNO-np exhibited higher efficiency for generating GSNO from GSH and maintained higher levels of GSNO concentration for longer time (24 h) as compared to SNO-np as well as a previously characterized nitric oxide releasing platform, NO-np (nitric oxide releasing nanoparticles).	S-Nitrosoglutathione	54-58	strawberry notch homolog 1	Homo sapiens	4-7
22705913-6	2012	NAC-SNO-np exhibited higher efficiency for generating GSNO from GSH and maintained higher levels of GSNO concentration for longer time (24 h) as compared to SNO-np as well as a previously characterized nitric oxide releasing platform, NO-np (nitric oxide releasing nanoparticles).	Glutathione	64-67	strawberry notch homolog 1	Homo sapiens	4-7
22705913-6	2012	NAC-SNO-np exhibited higher efficiency for generating GSNO from GSH and maintained higher levels of GSNO concentration for longer time (24 h) as compared to SNO-np as well as a previously characterized nitric oxide releasing platform, NO-np (nitric oxide releasing nanoparticles).	Glutathione	64-67	strawberry notch homolog 1	Homo sapiens	55-58
22705913-6	2012	NAC-SNO-np exhibited higher efficiency for generating GSNO from GSH and maintained higher levels of GSNO concentration for longer time (24 h) as compared to SNO-np as well as a previously characterized nitric oxide releasing platform, NO-np (nitric oxide releasing nanoparticles).	S-Nitrosoglutathione	100-104	strawberry notch homolog 1	Homo sapiens	4-7
22705913-6	2012	NAC-SNO-np exhibited higher efficiency for generating GSNO from GSH and maintained higher levels of GSNO concentration for longer time (24 h) as compared to SNO-np as well as a previously characterized nitric oxide releasing platform, NO-np (nitric oxide releasing nanoparticles).	Nitric Oxide	202-214	strawberry notch homolog 1	Homo sapiens	4-7
22705913-6	2012	NAC-SNO-np exhibited higher efficiency for generating GSNO from GSH and maintained higher levels of GSNO concentration for longer time (24 h) as compared to SNO-np as well as a previously characterized nitric oxide releasing platform, NO-np (nitric oxide releasing nanoparticles).	Nitric Oxide	242-254	strawberry notch homolog 1	Homo sapiens	4-7
22705913-9	2012	Together, these data suggest that the NAC-SNO-np represents a novel means to both study the biologic effects of nitrosothiols and effectively capitalize on its therapeutic potential.	S-Nitrosothiols	112-125	strawberry notch homolog 1	Homo sapiens	42-45
22777010-1	2012	SnO(2) nanorods with specific growth directions, [101] or [001], were fabricated on alpha-Fe(2)O(3) substrates via a simple hydrothermal method.	alpha-fe(2)o	84-96	strawberry notch homolog 1	Homo sapiens	0-3
22777010-3	2012	Both {11 20} and {10 10} facets of alpha-Fe(2)O(3) are favorable to direct the growth of SnO(2) nanorods.	alpha-fe(2)o	35-47	strawberry notch homolog 1	Homo sapiens	89-92
22777010-5	2012	Furthermore, the distribution and coordination of oxygen atoms at the interface of alpha-Fe(2)O(3)-SnO(2) heterostructure are analyzed, which reveals that only slight deviations from their original equilibrium positions are allowed for the formation of heterogeneous interface.	Oxygen	50-56	strawberry notch homolog 1	Homo sapiens	99-102
22777010-5	2012	Furthermore, the distribution and coordination of oxygen atoms at the interface of alpha-Fe(2)O(3)-SnO(2) heterostructure are analyzed, which reveals that only slight deviations from their original equilibrium positions are allowed for the formation of heterogeneous interface.	alpha-fe(2)o(3)	83-98	strawberry notch homolog 1	Homo sapiens	99-102
22733161-0	2012	CO oxidation on nanostructured SnO(x)/Pt(111) surfaces: unique properties of reduced SnO(x).	Platinum	38-40	strawberry notch homolog 1	Homo sapiens	85-88
22733161-3	2012	XPS data show that the SnO(x) nanoparticles are highly reduced with Sn(II)O being the dominant oxide species, but the relative concentration of Sn(II) in the SnO(x) nanoparticles decreases with increasing Sn coverage.	sn(ii)o	68-75	strawberry notch homolog 1	Homo sapiens	23-26
22733161-3	2012	XPS data show that the SnO(x) nanoparticles are highly reduced with Sn(II)O being the dominant oxide species, but the relative concentration of Sn(II) in the SnO(x) nanoparticles decreases with increasing Sn coverage.	Oxides	95-100	strawberry notch homolog 1	Homo sapiens	23-26
22733161-3	2012	XPS data show that the SnO(x) nanoparticles are highly reduced with Sn(II)O being the dominant oxide species, but the relative concentration of Sn(II) in the SnO(x) nanoparticles decreases with increasing Sn coverage.	sn(ii)	68-74	strawberry notch homolog 1	Homo sapiens	23-26
22733161-3	2012	XPS data show that the SnO(x) nanoparticles are highly reduced with Sn(II)O being the dominant oxide species, but the relative concentration of Sn(II) in the SnO(x) nanoparticles decreases with increasing Sn coverage.	Tin	23-25	strawberry notch homolog 1	Homo sapiens	158-161
22733161-7	2012	The occurrence of a non-CO oxidation reaction path involving reduced Sn(II)O species at higher SnO(x) coverages accounts for the decreased CO oxidation activity.	sn(ii)o	69-76	strawberry notch homolog 1	Homo sapiens	95-98
22728332-2	2012	The method is based on the catalytic reaction of C(2)H(2) over a mixture of both SnO(2) and In(2)O(3) particles.	Acetylene	49-57	strawberry notch homolog 1	Homo sapiens	81-84
22699499-1	2012	An efficient BiVO(4) thin film electrode for overall water splitting was prepared by dipping an F-doped SnO(2) (FTO) substrate electrode in an aqueous nitric acid solution of Bi(NO(3))(3) and NH(4)VO(3), and subsequently calcining it.	Bismuth	13-15	strawberry notch homolog 1	Homo sapiens	104-107
22592292-0	2012	An organometallic approach for ultrathin SnO(x)Fe(y)S(z) plates and their graphene composites as stable anode materials for high performance lithium ion batteries.	Lithium	141-148	strawberry notch homolog 1	Homo sapiens	41-44
22592292-1	2012	Through an organometallic approach, ultrathin SnO(x)Fe(y)S(z) plates with ~2 nm single layer-thicknesses were obtained and their graphene composites showed very promising discharge capacities of up to 736 mA h g(-1) and excellent stabilities as anode materials in lithium ion batteries.	Graphite	129-137	strawberry notch homolog 1	Homo sapiens	46-49
22592292-1	2012	Through an organometallic approach, ultrathin SnO(x)Fe(y)S(z) plates with ~2 nm single layer-thicknesses were obtained and their graphene composites showed very promising discharge capacities of up to 736 mA h g(-1) and excellent stabilities as anode materials in lithium ion batteries.	Lithium	264-271	strawberry notch homolog 1	Homo sapiens	46-49
22476795-1	2012	A novel ultraviolet (UV)-assisted imprinting procedure that employs photosensitive tin(II) 2-ethylhexanoate is presented for the facile size-tunable fabrication of functional tin dioxide (SnO(2)) nanostructures by varying annealing temperatures.	2-ethylhexanoic acid tin(II) salt	83-107	strawberry notch homolog 1	Homo sapiens	188-191
22476795-1	2012	A novel ultraviolet (UV)-assisted imprinting procedure that employs photosensitive tin(II) 2-ethylhexanoate is presented for the facile size-tunable fabrication of functional tin dioxide (SnO(2)) nanostructures by varying annealing temperatures.	stannic oxide	175-186	strawberry notch homolog 1	Homo sapiens	188-191
23025234-1	2012	In this paper, SnO(x) films were produced by reactive radio frequency magnetron sputtering under various oxygen partial pressure (P(O)) in conjunction with a thermal annealing at 200  C afterwards.	Oxygen	105-111	strawberry notch homolog 1	Homo sapiens	15-18
23025234-4	2012	The polycrystalline to amorphous film structure transition was ascribed to the enhanced crystallization temperature due to the perturbed structural disorder by incorporating Sn(4+) into the SnO matrix.	Tin(4+)	174-180	strawberry notch homolog 1	Homo sapiens	190-193
23073411-1	2012	The photoelastic constant (PEC) is evaluated for 15 zinc tin phosphate glasses in a series of xZnO-(67-x)SnO-33P(2)O(5) where x is 0-30 mol.	xzno	94-98	strawberry notch homolog 1	Homo sapiens	105-108
22918269-0	2012	An Au clusters related spill-over sensitization mechanism in SnO2-based gas sensors identified by operando HERFD-XAS, work function changes, DC resistance and catalytic conversion studies.	Gold	3-5	strawberry notch homolog 1	Homo sapiens	61-64
22885569-4	2012	Experimental results indicate that the XRD peak shift of SnO(2) to a larger angle increases with the increasing amount of Ga doping.	Gallium	122-124	strawberry notch homolog 1	Homo sapiens	57-60
22885569-6	2012	The maximum quantum efficiency of Ga(2)O(3)/SnO(2):Ga core-shell nanowires is around 0.362%.	Gallium	34-36	strawberry notch homolog 1	Homo sapiens	44-47
22885569-6	2012	The maximum quantum efficiency of Ga(2)O(3)/SnO(2):Ga core-shell nanowires is around 0.362%.	Gallium	51-53	strawberry notch homolog 1	Homo sapiens	44-47
22885569-7	2012	The UV light on-off current contrast ratio of Ga(2)O(3)/SnO(2):Ga core-shell nanowires is around 1066.7 at a bias of 5 V. Moreover, the dynamic response of Ga(2)O(3)/SnO(2):Ga core-shell nanowires has an on-off current contrast ratio of around 16.	ga(2)o	46-52	strawberry notch homolog 1	Homo sapiens	166-169
22885569-7	2012	The UV light on-off current contrast ratio of Ga(2)O(3)/SnO(2):Ga core-shell nanowires is around 1066.7 at a bias of 5 V. Moreover, the dynamic response of Ga(2)O(3)/SnO(2):Ga core-shell nanowires has an on-off current contrast ratio of around 16.	ga(2)o(3)	46-55	strawberry notch homolog 1	Homo sapiens	166-169
22885569-7	2012	The UV light on-off current contrast ratio of Ga(2)O(3)/SnO(2):Ga core-shell nanowires is around 1066.7 at a bias of 5 V. Moreover, the dynamic response of Ga(2)O(3)/SnO(2):Ga core-shell nanowires has an on-off current contrast ratio of around 16.	Gallium	63-65	strawberry notch homolog 1	Homo sapiens	56-59
22885569-7	2012	The UV light on-off current contrast ratio of Ga(2)O(3)/SnO(2):Ga core-shell nanowires is around 1066.7 at a bias of 5 V. Moreover, the dynamic response of Ga(2)O(3)/SnO(2):Ga core-shell nanowires has an on-off current contrast ratio of around 16.	Gallium	63-65	strawberry notch homolog 1	Homo sapiens	166-169
22746149-0	2012	Polyvinylpyrrolidone-assisted ultrasonic synthesis of SnO nanosheets and their use as conformal templates for tin dioxide nanostructures.	Povidone	0-20	strawberry notch homolog 1	Homo sapiens	54-57
22746149-0	2012	Polyvinylpyrrolidone-assisted ultrasonic synthesis of SnO nanosheets and their use as conformal templates for tin dioxide nanostructures.	stannic oxide	110-121	strawberry notch homolog 1	Homo sapiens	54-57
22746149-1	2012	Single crystalline SnO nanosheets with exposed {001} facets have been prepared by an ultrasonic aqueous synthesis in the presence of polyvinylpyrrolidone, which hinders the spontaneous formation of the truncated bipyramidal SnO microcrystals and exfoliate them into layer-by-layer hierarchical structures and further into separate SnO nanosheets.	Povidone	133-153	strawberry notch homolog 1	Homo sapiens	19-22
22746149-1	2012	Single crystalline SnO nanosheets with exposed {001} facets have been prepared by an ultrasonic aqueous synthesis in the presence of polyvinylpyrrolidone, which hinders the spontaneous formation of the truncated bipyramidal SnO microcrystals and exfoliate them into layer-by-layer hierarchical structures and further into separate SnO nanosheets.	Povidone	133-153	strawberry notch homolog 1	Homo sapiens	224-227
22746149-1	2012	Single crystalline SnO nanosheets with exposed {001} facets have been prepared by an ultrasonic aqueous synthesis in the presence of polyvinylpyrrolidone, which hinders the spontaneous formation of the truncated bipyramidal SnO microcrystals and exfoliate them into layer-by-layer hierarchical structures and further into separate SnO nanosheets.	Povidone	133-153	strawberry notch homolog 1	Homo sapiens	224-227
21397666-1	2012	BACKGROUND: Nitric oxide (NO) exerts powerful physiological effects through guanylate cyclase (GC), a non-mitochondrial enzyme, and through the generation of protein cysteinyl-NO (SNO) adducts-a post-translational modification relevant to mitochondrial biology.	Nitric Oxide	12-24	strawberry notch homolog 1	Homo sapiens	180-183
21397666-1	2012	BACKGROUND: Nitric oxide (NO) exerts powerful physiological effects through guanylate cyclase (GC), a non-mitochondrial enzyme, and through the generation of protein cysteinyl-NO (SNO) adducts-a post-translational modification relevant to mitochondrial biology.	cysteinyl-no	166-178	strawberry notch homolog 1	Homo sapiens	180-183
21397666-3	2012	SCOPE OF REVIEW: The principles by which mitochondrial SNO proteins are formed and their actions, independently or collectively with NO binding to heme, iron-sulfur centers, or to glutathione (GSH) are reviewed on a molecular background of SNO-based signal transduction.	Heme	147-151	strawberry notch homolog 1	Homo sapiens	55-58
21397666-3	2012	SCOPE OF REVIEW: The principles by which mitochondrial SNO proteins are formed and their actions, independently or collectively with NO binding to heme, iron-sulfur centers, or to glutathione (GSH) are reviewed on a molecular background of SNO-based signal transduction.	Iron	153-157	strawberry notch homolog 1	Homo sapiens	55-58
21397666-3	2012	SCOPE OF REVIEW: The principles by which mitochondrial SNO proteins are formed and their actions, independently or collectively with NO binding to heme, iron-sulfur centers, or to glutathione (GSH) are reviewed on a molecular background of SNO-based signal transduction.	Sulfur	158-164	strawberry notch homolog 1	Homo sapiens	55-58
21397666-3	2012	SCOPE OF REVIEW: The principles by which mitochondrial SNO proteins are formed and their actions, independently or collectively with NO binding to heme, iron-sulfur centers, or to glutathione (GSH) are reviewed on a molecular background of SNO-based signal transduction.	Glutathione	180-191	strawberry notch homolog 1	Homo sapiens	55-58
21397666-3	2012	SCOPE OF REVIEW: The principles by which mitochondrial SNO proteins are formed and their actions, independently or collectively with NO binding to heme, iron-sulfur centers, or to glutathione (GSH) are reviewed on a molecular background of SNO-based signal transduction.	Glutathione	193-196	strawberry notch homolog 1	Homo sapiens	55-58
21397666-4	2012	MAJOR CONCLUSIONS: Mitochondrial SNO-proteins have been demonstrated to inhibit Complex I of the electron transport chain, to modulate mitochondrial reactive oxygen species (ROS) production, influence calcium-dependent opening of the mitochondrial permeability transition pore (MPTP), promote selective importation of mitochondrial protein, and stimulate mitochondrial fission.	Reactive Oxygen Species	149-172	strawberry notch homolog 1	Homo sapiens	33-36
21397666-4	2012	MAJOR CONCLUSIONS: Mitochondrial SNO-proteins have been demonstrated to inhibit Complex I of the electron transport chain, to modulate mitochondrial reactive oxygen species (ROS) production, influence calcium-dependent opening of the mitochondrial permeability transition pore (MPTP), promote selective importation of mitochondrial protein, and stimulate mitochondrial fission.	Reactive Oxygen Species	174-177	strawberry notch homolog 1	Homo sapiens	33-36
21397666-4	2012	MAJOR CONCLUSIONS: Mitochondrial SNO-proteins have been demonstrated to inhibit Complex I of the electron transport chain, to modulate mitochondrial reactive oxygen species (ROS) production, influence calcium-dependent opening of the mitochondrial permeability transition pore (MPTP), promote selective importation of mitochondrial protein, and stimulate mitochondrial fission.	Calcium	201-208	strawberry notch homolog 1	Homo sapiens	33-36
21397666-5	2012	The ease of reversibility and the affirmation of regulated S-nitros(yl)ating and denitros(yl)ating enzymatic reactions support hypotheses that SNO regulates the mitochondrion through redox mechanisms.	Sulfur	59-61	strawberry notch homolog 1	Homo sapiens	143-146
21397666-5	2012	The ease of reversibility and the affirmation of regulated S-nitros(yl)ating and denitros(yl)ating enzymatic reactions support hypotheses that SNO regulates the mitochondrion through redox mechanisms.	nitros	61-67	strawberry notch homolog 1	Homo sapiens	143-146
21397666-5	2012	The ease of reversibility and the affirmation of regulated S-nitros(yl)ating and denitros(yl)ating enzymatic reactions support hypotheses that SNO regulates the mitochondrion through redox mechanisms.	tyrosylleucine	68-70	strawberry notch homolog 1	Homo sapiens	143-146
21397666-5	2012	The ease of reversibility and the affirmation of regulated S-nitros(yl)ating and denitros(yl)ating enzymatic reactions support hypotheses that SNO regulates the mitochondrion through redox mechanisms.	denitros(yl	81-92	strawberry notch homolog 1	Homo sapiens	143-146
21440604-3	2012	MAJOR CONCLUSIONS: Structural characterization of SNO-proteins by X-ray crystallography is increasingly being utilized to understand both the relationships between protein structure and Cys thiol reactivity as well as the consequences of S-nitrosylation on protein structure and function.	Cysteine	186-189	strawberry notch homolog 1	Homo sapiens	50-53
21440604-3	2012	MAJOR CONCLUSIONS: Structural characterization of SNO-proteins by X-ray crystallography is increasingly being utilized to understand both the relationships between protein structure and Cys thiol reactivity as well as the consequences of S-nitrosylation on protein structure and function.	Sulfhydryl Compounds	190-195	strawberry notch homolog 1	Homo sapiens	50-53
22422051-2	2012	Herein, we report a large-scale synthesis of a SnO(2)/alpha-Fe(2)O(3) composite nanotube array on a stainless steel substrate via a ZnO nanowire array as an in situ sacrificial template without using any strong acid or alkali.	Stainless Steel	100-115	strawberry notch homolog 1	Homo sapiens	47-50
22422051-2	2012	Herein, we report a large-scale synthesis of a SnO(2)/alpha-Fe(2)O(3) composite nanotube array on a stainless steel substrate via a ZnO nanowire array as an in situ sacrificial template without using any strong acid or alkali.	Zinc Oxide	132-135	strawberry notch homolog 1	Homo sapiens	47-50
22422051-3	2012	Importantly, both SnO(2) and alpha-Fe(2)O(3) contribute to the lithium storage, and the hybridization of SnO(2) and alpha-Fe(2)O(3) into an integrated nanotube structure provides them with an elegant synergistic effect when participating in electrochemical reactions.	Lithium	63-70	strawberry notch homolog 1	Homo sapiens	18-21
22266637-2	2012	In the proposed synthetic method, octahedral SnO(2)  nanoparticles enclosed by high-energy {111} facets were successfully synthesized for the first time, and tetramethylammonium hydroxide was found to be crucial for the control of exposed facets.	tetramethylammonium	158-187	strawberry notch homolog 1	Homo sapiens	45-48
22364571-4	2012	Our experimental results revealed that the relationship between the Hammett constant and rate constant for the electrochemical oxidation of phenolic compounds at the RuO(2)-SnO(2)-Sb(2)O(5) electrode was different from the results obtained at a platinum electrode.	Platinum	245-253	strawberry notch homolog 1	Homo sapiens	173-176
22276802-1	2012	This paper describes a new synthesis and lithium ion charge-discharge property of tin dioxide (SnO(2)) hollow nanocubes.	Lithium	41-48	strawberry notch homolog 1	Homo sapiens	95-98
22276802-1	2012	This paper describes a new synthesis and lithium ion charge-discharge property of tin dioxide (SnO(2)) hollow nanocubes.	stannic oxide	82-93	strawberry notch homolog 1	Homo sapiens	95-98
22276802-2	2012	SnO(2) is one of the best-known anode materials for lithium-ion battery application because of its high lithiation-delithiation capacity.	Lithium	52-59	strawberry notch homolog 1	Homo sapiens	0-3
22252288-1	2012	We report an ultrafast and sensitive hydrogen (H(2)) sensing platform using semiconducting single-walled carbon nanotubes (SWCNTs) decorated with tin oxide (SnO(2)) nanocrystals (NCs).	Hydrogen	37-45	strawberry notch homolog 1	Homo sapiens	157-160
22252288-1	2012	We report an ultrafast and sensitive hydrogen (H(2)) sensing platform using semiconducting single-walled carbon nanotubes (SWCNTs) decorated with tin oxide (SnO(2)) nanocrystals (NCs).	Hydrogen	47-52	strawberry notch homolog 1	Homo sapiens	157-160
22252288-1	2012	We report an ultrafast and sensitive hydrogen (H(2)) sensing platform using semiconducting single-walled carbon nanotubes (SWCNTs) decorated with tin oxide (SnO(2)) nanocrystals (NCs).	stannic oxide	146-155	strawberry notch homolog 1	Homo sapiens	157-160
22252288-2	2012	The hybrid SnO(2) NC-SWCNT platform shows a response time of 2-3 seconds to 1% H(2) under room temperature and can fully recover within a few minutes in air.	Hydrogen	79-83	strawberry notch homolog 1	Homo sapiens	11-14
22196347-0	2012	Effect of plasma etching on photoluminescence of SnO(x)/Sn nanoparticles deposited on DOPC lipid membrane.	1,2-oleoylphosphatidylcholine	86-90	strawberry notch homolog 1	Homo sapiens	49-52
22108293-3	2011	The as-synthesized SnO(2) nanoshuttles showed ultrahigh flexibility and strong toughness with a large elastic strain of ~ 6.2, which is much higher than reported for Si and ZnO nanowire as well as most crystalline metallic materials.	Silicon	166-168	strawberry notch homolog 1	Homo sapiens	19-22
22196347-1	2012	The photoluminescence characteristic of the SnO(x)/Sn nanoparticles deposited on a solid supported liquid-crystalline phospholipid (1,2-dioleoyl-sn-glycero-3-phosphocholine) membrane was probed after plasma etching the nanoparticle monolayer.	Phospholipids	118-130	strawberry notch homolog 1	Homo sapiens	44-47
22196347-1	2012	The photoluminescence characteristic of the SnO(x)/Sn nanoparticles deposited on a solid supported liquid-crystalline phospholipid (1,2-dioleoyl-sn-glycero-3-phosphocholine) membrane was probed after plasma etching the nanoparticle monolayer.	1,2-oleoylphosphatidylcholine	132-172	strawberry notch homolog 1	Homo sapiens	44-47
22196347-4	2012	It was also shown that hydrating the SnO(x)/Sn nanoparticles similarly improved the PL response of the nanoparticles as the hydration produced an additional oxygen-rich oxide layer on the particle surface.	Oxygen	157-163	strawberry notch homolog 1	Homo sapiens	37-40
22196347-4	2012	It was also shown that hydrating the SnO(x)/Sn nanoparticles similarly improved the PL response of the nanoparticles as the hydration produced an additional oxygen-rich oxide layer on the particle surface.	rich oxide	164-174	strawberry notch homolog 1	Homo sapiens	37-40
22100619-4	2012	In the current study we report the use of triphenylphosphine ester derivatives to selectively reduce SNO bonds in proteins.	triphenylphosphine ester	42-66	strawberry notch homolog 1	Homo sapiens	101-104
22666053-3	2012	To overcome this limitation, the catalytic activity of Cr(2)O(3), SnO(2), Fe(2)O(3) and NiO powders were evaluated for their selective ethanol oxidation ability.	Ethanol	135-142	strawberry notch homolog 1	Homo sapiens	66-69
22666053-4	2012	Among these oxides, SnO(2) was found to selectively oxidize C(2)H(5)OH, thus improving C(7)H(8) selectivity.	Oxides	12-18	strawberry notch homolog 1	Homo sapiens	20-23
22058077-1	2011	A facile bottom-up synthesis approach is developed to prepare porous metal-oxide ultrathin sheets, e.g., SnO(2), Fe(2)O(3), and SnO(2)-Fe(2)O(3), with thicknesses of ~5 nm.	metal-oxide	69-80	strawberry notch homolog 1	Homo sapiens	105-108
22058077-1	2011	A facile bottom-up synthesis approach is developed to prepare porous metal-oxide ultrathin sheets, e.g., SnO(2), Fe(2)O(3), and SnO(2)-Fe(2)O(3), with thicknesses of ~5 nm.	metal-oxide	69-80	strawberry notch homolog 1	Homo sapiens	128-131
22108293-3	2011	The as-synthesized SnO(2) nanoshuttles showed ultrahigh flexibility and strong toughness with a large elastic strain of ~ 6.2, which is much higher than reported for Si and ZnO nanowire as well as most crystalline metallic materials.	Zinc Oxide	173-176	strawberry notch homolog 1	Homo sapiens	19-22
22108293-4	2011	The field emitter fabricated using SnO(2) nanoshuttle arrays has a low turn-on electric field of around 0.6 V microm(-1), and a high field emission current density of above 10 mA cm(-2), which is comparable with the highest emission current density of carbon nanotube and nanowire field emitters.	Carbon	252-258	strawberry notch homolog 1	Homo sapiens	35-38
21822146-2	2011	We hypothesized that formation of thienopyridine-derived nitrosothiols (ticlopidine-SNO, clopidogrel-SNO, and prasugrel-SNO) occurs directly from the respective parent drug.	thienopyridine	34-48	strawberry notch homolog 1	Homo sapiens	84-87
22006643-7	2011	These results might rationalize that the known protein-Cys-SNO sites derived from DNICs were located adjacent to acid and base motifs, and no protein-bound SNO characterized to date has been directly derived from [protein-(cysteine)(2)Fe(NO)(2)] in biology.	Cysteine	55-58	strawberry notch homolog 1	Homo sapiens	59-62
21956966-6	2011	The content of metal in the particles was up to 12 wt %, and estimations by thermogravimetrical indicated that at least 96% of the total organotin compound was converted to SnO(2).	Metals	15-20	strawberry notch homolog 1	Homo sapiens	173-176
21822146-2	2011	We hypothesized that formation of thienopyridine-derived nitrosothiols (ticlopidine-SNO, clopidogrel-SNO, and prasugrel-SNO) occurs directly from the respective parent drug.	thienopyridine	34-48	strawberry notch homolog 1	Homo sapiens	101-104
21822146-2	2011	We hypothesized that formation of thienopyridine-derived nitrosothiols (ticlopidine-SNO, clopidogrel-SNO, and prasugrel-SNO) occurs directly from the respective parent drug.	thienopyridine	34-48	strawberry notch homolog 1	Homo sapiens	101-104
21822146-2	2011	We hypothesized that formation of thienopyridine-derived nitrosothiols (ticlopidine-SNO, clopidogrel-SNO, and prasugrel-SNO) occurs directly from the respective parent drug.	S-Nitrosothiols	57-70	strawberry notch homolog 1	Homo sapiens	84-87
21822146-2	2011	We hypothesized that formation of thienopyridine-derived nitrosothiols (ticlopidine-SNO, clopidogrel-SNO, and prasugrel-SNO) occurs directly from the respective parent drug.	S-Nitrosothiols	57-70	strawberry notch homolog 1	Homo sapiens	101-104
21822146-2	2011	We hypothesized that formation of thienopyridine-derived nitrosothiols (ticlopidine-SNO, clopidogrel-SNO, and prasugrel-SNO) occurs directly from the respective parent drug.	S-Nitrosothiols	57-70	strawberry notch homolog 1	Homo sapiens	101-104
21822146-2	2011	We hypothesized that formation of thienopyridine-derived nitrosothiols (ticlopidine-SNO, clopidogrel-SNO, and prasugrel-SNO) occurs directly from the respective parent drug.	Ticlopidine	72-83	strawberry notch homolog 1	Homo sapiens	84-87
21822146-2	2011	We hypothesized that formation of thienopyridine-derived nitrosothiols (ticlopidine-SNO, clopidogrel-SNO, and prasugrel-SNO) occurs directly from the respective parent drug.	Clopidogrel	89-100	strawberry notch homolog 1	Homo sapiens	101-104
21822146-2	2011	We hypothesized that formation of thienopyridine-derived nitrosothiols (ticlopidine-SNO, clopidogrel-SNO, and prasugrel-SNO) occurs directly from the respective parent drug.	Clopidogrel	89-100	strawberry notch homolog 1	Homo sapiens	101-104
21822146-5	2011	Increasing nitrite availability resulted in increased Th-SNO formation for all drugs (other than ticlopidine).	Nitrites	11-18	strawberry notch homolog 1	Homo sapiens	57-60
21822146-7	2011	Clopidogrel-chloride-SNO displayed rapid-release kinetics in a chemical environment, which was reflected by immediate and transient vasorelaxation when compared with the SNO derivatives of the other thienopyridines.	Thienopyridines	199-214	strawberry notch homolog 1	Homo sapiens	21-24
21822146-8	2011	Accounting for differences in yield, clopidogrel-chloride-SNO exhibited the greatest propensity to immediately relax vascular tissue.	clopidogrel-chloride	37-57	strawberry notch homolog 1	Homo sapiens	58-61
21822146-10	2011	Differences in SNO yield and vasoactivity exist between thienopyridine preparations that might be important to our understanding of the direct pharmacological effectiveness of thienopyridines on vascular and platelet function.	thienopyridine	56-70	strawberry notch homolog 1	Homo sapiens	15-18
21822146-10	2011	Differences in SNO yield and vasoactivity exist between thienopyridine preparations that might be important to our understanding of the direct pharmacological effectiveness of thienopyridines on vascular and platelet function.	Thienopyridines	176-191	strawberry notch homolog 1	Homo sapiens	15-18
21911924-6	2011	The decomposition process is observed by resistively heating an SnO(2)/TiO(2) core-shell structure.	tio	71-74	strawberry notch homolog 1	Homo sapiens	64-67
21861510-1	2011	In this study, we successfully prepare SnO(2) nanoparticles inside the pore channels of CMK-3 ordered mesoporous carbon via sonochemical method.	Carbon	113-119	strawberry notch homolog 1	Homo sapiens	39-42
21781009-1	2011	Endogenous S-nitrosated human serum albumin (E-Mono-SNO-HSA) is a large molecular weight nitric oxide (NO) carrier in human plasma, which has shown many beneficial effects in different animal models.	Nitric Oxide	89-101	strawberry notch homolog 1	Homo sapiens	52-55
21781009-2	2011	To construct more efficient SNO-HSA preparations, SNO-HSA with many conjugated SNO groups has been prepared using chemical modification (CM-Poly-SNO-HSA).	Altretamine	32-35	strawberry notch homolog 1	Homo sapiens	28-31
21781009-2	2011	To construct more efficient SNO-HSA preparations, SNO-HSA with many conjugated SNO groups has been prepared using chemical modification (CM-Poly-SNO-HSA).	Altretamine	32-35	strawberry notch homolog 1	Homo sapiens	50-53
21781009-2	2011	To construct more efficient SNO-HSA preparations, SNO-HSA with many conjugated SNO groups has been prepared using chemical modification (CM-Poly-SNO-HSA).	Altretamine	32-35	strawberry notch homolog 1	Homo sapiens	50-53
21781009-2	2011	To construct more efficient SNO-HSA preparations, SNO-HSA with many conjugated SNO groups has been prepared using chemical modification (CM-Poly-SNO-HSA).	Altretamine	32-35	strawberry notch homolog 1	Homo sapiens	50-53
21781009-2	2011	To construct more efficient SNO-HSA preparations, SNO-HSA with many conjugated SNO groups has been prepared using chemical modification (CM-Poly-SNO-HSA).	Altretamine	54-57	strawberry notch homolog 1	Homo sapiens	28-31
21781009-2	2011	To construct more efficient SNO-HSA preparations, SNO-HSA with many conjugated SNO groups has been prepared using chemical modification (CM-Poly-SNO-HSA).	Altretamine	54-57	strawberry notch homolog 1	Homo sapiens	50-53
21781009-2	2011	To construct more efficient SNO-HSA preparations, SNO-HSA with many conjugated SNO groups has been prepared using chemical modification (CM-Poly-SNO-HSA).	Altretamine	54-57	strawberry notch homolog 1	Homo sapiens	50-53
21781009-2	2011	To construct more efficient SNO-HSA preparations, SNO-HSA with many conjugated SNO groups has been prepared using chemical modification (CM-Poly-SNO-HSA).	Altretamine	54-57	strawberry notch homolog 1	Homo sapiens	50-53
21781009-4	2011	Cellular uptake of NO from E-Mono-SNO-HSA partly takes place via low molecular weight thiol, and it results in cytoprotective effects by induction of heme oxygenase-1.	Sulfhydryl Compounds	86-91	strawberry notch homolog 1	Homo sapiens	34-37
21781009-8	2011	Thus, increasing the number of SNO groups on HSA does not simply intensify the cellular responses to the product but can also result in very different effects.	Altretamine	45-48	strawberry notch homolog 1	Homo sapiens	31-34
21813965-1	2011	Using first-principles calculations we have studied the electronic and structural properties of cation vacancies and their complexes with hydrogen impurities in SnO(2), In(2)O(3) and beta-Ga(2)O(3).	Hydrogen	138-146	strawberry notch homolog 1	Homo sapiens	161-164
21542642-5	2011	The SnO(2) nanowires coated with carbon, aluminum, or copper can be charged about 10 times faster than the noncoated ones.	Carbon	33-39	strawberry notch homolog 1	Homo sapiens	4-7
21766849-6	2011	The results demonstrate that the CuAAC "click" reaction can be used to form electrochemically and photoelectrochemically active molecular interfaces to SnO(2) and other metal oxide semiconductors.	metal oxide	169-180	strawberry notch homolog 1	Homo sapiens	152-155
22619954-1	2011	The efficiency and the mechanism of aniline degradation by an electrochemical oxidation process using a Ti/SnO2-Sb2O5 electrode as the anode and a graphite electrode as the cathode, were studied in two aqueous electrolytes with/without Fe2+.	aniline	36-43	strawberry notch homolog 1	Homo sapiens	107-110
21771632-1	2011	OBJECTIVE: To investigate the effect of particle size distribution of opacifier tin dioxides (SnO(2)) on the color of dental opaque porcelain for pure titanium by spectrophotometer.	stannic oxide	80-92	strawberry notch homolog 1	Homo sapiens	94-97
21238970-2	2011	In this study we have synthesized new polyethyleneimine (PEI) functionalized Mn(2)O(3), SiO(2), SnO(2), and ZrO(2) particles for the fabrication of packed capillary columns for CEC and CLC.	Polyethyleneimine	38-55	strawberry notch homolog 1	Homo sapiens	96-99
21238970-2	2011	In this study we have synthesized new polyethyleneimine (PEI) functionalized Mn(2)O(3), SiO(2), SnO(2), and ZrO(2) particles for the fabrication of packed capillary columns for CEC and CLC.	Polyethyleneimine	57-60	strawberry notch homolog 1	Homo sapiens	96-99
21542642-5	2011	The SnO(2) nanowires coated with carbon, aluminum, or copper can be charged about 10 times faster than the noncoated ones.	Aluminum	41-49	strawberry notch homolog 1	Homo sapiens	4-7
21542642-5	2011	The SnO(2) nanowires coated with carbon, aluminum, or copper can be charged about 10 times faster than the noncoated ones.	Copper	54-60	strawberry notch homolog 1	Homo sapiens	4-7
21454942-0	2011	Obviating the requirement for oxygen in SnO2-based solid-state dye-sensitized solar cells.	Oxygen	30-36	strawberry notch homolog 1	Homo sapiens	40-43
20603223-0	2011	Comments on the article "Nitrosylated human serum albumin (SNO-HSA) induces apoptosis in tumor cells (Nitric Oxide 22 (2010) 259-265)".	Nitric Oxide	102-114	strawberry notch homolog 1	Homo sapiens	59-62
21469708-2	2011	A variety of nanostructured oxides including TiO(2), SnO(2) and organosilicates are formed using sol-gel and nanoparticle precursors by way of molding with water-soluble polymeric templates generated from silicon masters.	Oxides	28-34	strawberry notch homolog 1	Homo sapiens	53-56
21469708-2	2011	A variety of nanostructured oxides including TiO(2), SnO(2) and organosilicates are formed using sol-gel and nanoparticle precursors by way of molding with water-soluble polymeric templates generated from silicon masters.	Water	156-161	strawberry notch homolog 1	Homo sapiens	53-56
21405047-0	2011	Experimental and theoretical studies of the thermal behavior of titanium dioxide-SnO2 based composites.	titanium dioxide	64-80	strawberry notch homolog 1	Homo sapiens	81-84
21292279-0	2011	Self-assembly of disk-like multiring ZnO-SnO2 colloidal nanoparticles.	Zinc Oxide	37-40	strawberry notch homolog 1	Homo sapiens	41-44
21292279-1	2011	ZnO-SnO(2) colloidal nanoparticles have been successfully synthesized by using the composite of ZnCl(2) and Sn(OC(4)H(9))(4) as inorganic precursor and dodecylbenzenesulfonic acid (DBSA) as an organic template.	Zinc Oxide	0-3	strawberry notch homolog 1	Homo sapiens	4-7
21292279-2	2011	The assembled nanostructures of ZnO-SnO(2) products have been carefully investigated by powder X-ray diffraction (XRD) and transmission electron microscopy (TEM).	Zinc Oxide	32-35	strawberry notch homolog 1	Homo sapiens	36-39
21292279-3	2011	It is found that ZnO-SnO(2) colloidal nanoparticles take a disk-like multiring nanostructure.	Zinc Oxide	17-20	strawberry notch homolog 1	Homo sapiens	21-24
21292279-4	2011	This interesting structure is predominantly determined by the tenacity for ZnO-SnO(2) mixtures to stabilize lamellae.	Zinc Oxide	75-78	strawberry notch homolog 1	Homo sapiens	79-82
21365094-5	2011	From the transmittance spectra, the fundamental absorption edge is found to be decreased with the Fe composition due to the joint contributions from SnO(2) and Fe(2)O(3).	Iron	98-100	strawberry notch homolog 1	Homo sapiens	149-152
21405047-1	2011	In this paper we report experimental and theoretical studies concerning the thermal behavior of some organotin-Ti(IV) oxides employed as precursors for TiO(2)/SnO(2) semiconducting based composites, with photocatalytic properties.	Oxides	118-124	strawberry notch homolog 1	Homo sapiens	159-162
21405047-1	2011	In this paper we report experimental and theoretical studies concerning the thermal behavior of some organotin-Ti(IV) oxides employed as precursors for TiO(2)/SnO(2) semiconducting based composites, with photocatalytic properties.	titanium dioxide	152-158	strawberry notch homolog 1	Homo sapiens	159-162
21387501-0	2011	The structure and behavior of platinum in SnO2-based sensors under working conditions.	Platinum	30-38	strawberry notch homolog 1	Homo sapiens	42-45
21368404-2	2011	The inorganic building unit is an Sn(4)O(12) cluster which is composed of edge-sharing SnO(4) and SnO(5) polyhedra.	polyhedra	105-114	strawberry notch homolog 1	Homo sapiens	98-101
21126092-1	2011	Commercial graphene nanoplatelets in the form of optically transparent thin films on F-doped SnO(2) (FTO) exhibited high electrocatalytic activity toward I(3)(-)/I(-) redox couple, particularly in electrolyte based on ionic liquid (Z952).	Graphite	11-19	strawberry notch homolog 1	Homo sapiens	93-96
21145751-10	2011	SnO(2)-based (68)Ge/(68)Ga generator elutes at 0.6 M HCl &gt;100% of the (68)Ga activity at calibration time and +-75% after 300 days.	Hydrochloric Acid	53-56	strawberry notch homolog 1	Homo sapiens	0-3
21446511-3	2011	TEM analysis and X-ray diffraction (XRD) results indicate that the Bi2O3-core/SnO2-shell nanowires consist of pure tetragonal alpha-Bi2O3-phase momocrystalline cores and tetragonal SnO2-phase polycrystalline shells.	bi2o3	67-72	strawberry notch homolog 1	Homo sapiens	78-81
21446511-3	2011	TEM analysis and X-ray diffraction (XRD) results indicate that the Bi2O3-core/SnO2-shell nanowires consist of pure tetragonal alpha-Bi2O3-phase momocrystalline cores and tetragonal SnO2-phase polycrystalline shells.	bi2o3	67-72	strawberry notch homolog 1	Homo sapiens	181-184
21446511-5	2011	On the other hand, the Bi2O3-core/SnO2-shell coaxial nanowires with the sputtering times of 4 and 8 min have a blue emission band centered at around 450 nm.	bi2o3	23-28	strawberry notch homolog 1	Homo sapiens	34-37
21031191-1	2010	New 1-D SnO(2)@C core-shell nanochains built into 3-D superstructures are presented for the first time as anode materials for lithium-ion batteries.	Lithium	126-133	strawberry notch homolog 1	Homo sapiens	8-11
22319350-2	2011	The mesopores and macropores of various SnO(2)-based powders were controlled by self-assembly of sodium bis(2-ethylhexyl)sulfosuccinate and polymethyl-methacrylate (PMMA) microspheres (ca.	Polymethyl Methacrylate	140-163	strawberry notch homolog 1	Homo sapiens	40-43
22319350-2	2011	The mesopores and macropores of various SnO(2)-based powders were controlled by self-assembly of sodium bis(2-ethylhexyl)sulfosuccinate and polymethyl-methacrylate (PMMA) microspheres (ca.	Polymethyl Methacrylate	165-169	strawberry notch homolog 1	Homo sapiens	40-43
22319350-6	2011	The addition of SiO(2) into mesoporous and/or macroporous SnO(2) was found to increase the sensor resistance in air, whereas doping of Sb(2)O(5) into mesoporous and/or macroporous SnO(2) was found to markedly reduce the sensor resistance in air, and to increase the response to 1,000 ppm H(2) as well as 1 ppm NO(2) in air.	Silicon Dioxide	16-22	strawberry notch homolog 1	Homo sapiens	58-61
22319350-7	2011	Among all the sensors tested, meso-macroporous SnO(2) added with 1 wt% SiO(2) and 5 wt% Sb(2)O(5), which were prepared with the above two templates simultaneously, exhibited the largest H(2) and NO(2) responses.	silicon monoxide	71-74	strawberry notch homolog 1	Homo sapiens	47-50
21266258-1	2011	Oxidative and nitrosative stress result in the accumulation of reactive oxygen and nitrogen species (ROS/RNS) which trigger redox-mediated signaling cascades through posttranslational modifications on cysteine residues, including S-nitrosylation (P-SNO) and S-glutathionylation (P-SSG).	reactive oxygen and nitrogen species	63-99	strawberry notch homolog 1	Homo sapiens	249-252
21266258-1	2011	Oxidative and nitrosative stress result in the accumulation of reactive oxygen and nitrogen species (ROS/RNS) which trigger redox-mediated signaling cascades through posttranslational modifications on cysteine residues, including S-nitrosylation (P-SNO) and S-glutathionylation (P-SSG).	ros	101-104	strawberry notch homolog 1	Homo sapiens	249-252
21266258-1	2011	Oxidative and nitrosative stress result in the accumulation of reactive oxygen and nitrogen species (ROS/RNS) which trigger redox-mediated signaling cascades through posttranslational modifications on cysteine residues, including S-nitrosylation (P-SNO) and S-glutathionylation (P-SSG).	Radon	105-108	strawberry notch homolog 1	Homo sapiens	249-252
21266258-1	2011	Oxidative and nitrosative stress result in the accumulation of reactive oxygen and nitrogen species (ROS/RNS) which trigger redox-mediated signaling cascades through posttranslational modifications on cysteine residues, including S-nitrosylation (P-SNO) and S-glutathionylation (P-SSG).	Cysteine	201-209	strawberry notch homolog 1	Homo sapiens	249-252
22163690-4	2011	X-ray diffraction analysis confirms that SnO(x) thin films consist of a polycrystalline structure with an average grain size of 36 nm.	polycrystalline	72-87	strawberry notch homolog 1	Homo sapiens	41-44
21031191-2	2010	These novel SnO(2)@C core-shell nanochains exhibit desirable lithium storage properties.	Lithium	61-68	strawberry notch homolog 1	Homo sapiens	12-15
20225886-1	2010	Photoinduced interfacial electron transfer (IET) in sulforhodamine B (SRhB)-aminosilane-Tin oxide (SnO(2)) nanoparticle donor-bridge-acceptor complexes has been studied on a single molecule and ensemble average level.	1-(4-CYANO-PHENYL)-3-[2-(2,6-DICHLORO-PHENYL)-1-IMINO-ETHYL]-THIOUREA	44-47	strawberry notch homolog 1	Homo sapiens	99-102
21049941-0	2010	Novel heteroleptic heterobimetallic alkoxide complexes as facile single-source precursors for Ta(5+) doped TiO(2)-SnO(2) nanoparticles.	alkoxide	36-44	strawberry notch homolog 1	Homo sapiens	114-117
21049941-0	2010	Novel heteroleptic heterobimetallic alkoxide complexes as facile single-source precursors for Ta(5+) doped TiO(2)-SnO(2) nanoparticles.	ta(5+) doped	94-106	strawberry notch homolog 1	Homo sapiens	114-117
21049941-0	2010	Novel heteroleptic heterobimetallic alkoxide complexes as facile single-source precursors for Ta(5+) doped TiO(2)-SnO(2) nanoparticles.	titanium dioxide	107-113	strawberry notch homolog 1	Homo sapiens	114-117
21049941-4	2010	Facile conversion of these precursors to halide-free spinodal form of Ta(5+)-doped TiO(2)-SnO(2) as a potential thermoelectric material is reported.	halide	41-47	strawberry notch homolog 1	Homo sapiens	90-93
21049941-4	2010	Facile conversion of these precursors to halide-free spinodal form of Ta(5+)-doped TiO(2)-SnO(2) as a potential thermoelectric material is reported.	ta(5+)-doped	70-82	strawberry notch homolog 1	Homo sapiens	90-93
21049941-4	2010	Facile conversion of these precursors to halide-free spinodal form of Ta(5+)-doped TiO(2)-SnO(2) as a potential thermoelectric material is reported.	titanium dioxide	83-89	strawberry notch homolog 1	Homo sapiens	90-93
21077091-2	2010	Herein, we present an unambiguous and rigorous theoretical analysis in order to explain why and how the oxygen vacancies affect the n-type semiconductors alpha-Fe(2)O(3) and Fe-doped SnO(2), in which they are both electronically and chemically transformed into a p-type semiconductor.	Oxygen	104-110	strawberry notch homolog 1	Homo sapiens	183-186
21124593-1	2010	We designed and fabricated multilayer metal/metal-oxide surface relief diffractive grating structures by growing alternating Pt and SnO(x) layers.	Metals	38-43	strawberry notch homolog 1	Homo sapiens	132-135
21124593-1	2010	We designed and fabricated multilayer metal/metal-oxide surface relief diffractive grating structures by growing alternating Pt and SnO(x) layers.	metal-oxide	44-55	strawberry notch homolog 1	Homo sapiens	132-135
20225886-1	2010	Photoinduced interfacial electron transfer (IET) in sulforhodamine B (SRhB)-aminosilane-Tin oxide (SnO(2)) nanoparticle donor-bridge-acceptor complexes has been studied on a single molecule and ensemble average level.	lissamine rhodamine B	52-68	strawberry notch homolog 1	Homo sapiens	99-102
20225886-1	2010	Photoinduced interfacial electron transfer (IET) in sulforhodamine B (SRhB)-aminosilane-Tin oxide (SnO(2)) nanoparticle donor-bridge-acceptor complexes has been studied on a single molecule and ensemble average level.	lissamine rhodamine B	70-74	strawberry notch homolog 1	Homo sapiens	99-102
20225886-1	2010	Photoinduced interfacial electron transfer (IET) in sulforhodamine B (SRhB)-aminosilane-Tin oxide (SnO(2)) nanoparticle donor-bridge-acceptor complexes has been studied on a single molecule and ensemble average level.	aminosilane-tin oxide	76-97	strawberry notch homolog 1	Homo sapiens	99-102
20225886-3	2010	Shorter fluorescence lifetime on SnO(2) than on ZrO(2) is observed and attributed to IET from SRhB to SnO(2).	zro	48-51	strawberry notch homolog 1	Homo sapiens	33-36
20225886-3	2010	Shorter fluorescence lifetime on SnO(2) than on ZrO(2) is observed and attributed to IET from SRhB to SnO(2).	zro	48-51	strawberry notch homolog 1	Homo sapiens	102-105
20225886-3	2010	Shorter fluorescence lifetime on SnO(2) than on ZrO(2) is observed and attributed to IET from SRhB to SnO(2).	1-(4-CYANO-PHENYL)-3-[2-(2,6-DICHLORO-PHENYL)-1-IMINO-ETHYL]-THIOUREA	85-88	strawberry notch homolog 1	Homo sapiens	33-36
20225886-3	2010	Shorter fluorescence lifetime on SnO(2) than on ZrO(2) is observed and attributed to IET from SRhB to SnO(2).	1-(4-CYANO-PHENYL)-3-[2-(2,6-DICHLORO-PHENYL)-1-IMINO-ETHYL]-THIOUREA	85-88	strawberry notch homolog 1	Homo sapiens	102-105
20225886-3	2010	Shorter fluorescence lifetime on SnO(2) than on ZrO(2) is observed and attributed to IET from SRhB to SnO(2).	lissamine rhodamine B	94-98	strawberry notch homolog 1	Homo sapiens	33-36
20225886-3	2010	Shorter fluorescence lifetime on SnO(2) than on ZrO(2) is observed and attributed to IET from SRhB to SnO(2).	lissamine rhodamine B	94-98	strawberry notch homolog 1	Homo sapiens	102-105
20820686-0	2010	Hydrothermal synthesis of alpha-Fe(2)O(3)@SnO(2) core-shell nanotubes for highly selective enrichment of phosphopeptides for mass spectrometry analysis.	alpha-fe(2)o	26-38	strawberry notch homolog 1	Homo sapiens	42-45
20941057-1	2010	We first investigated the alignment characteristics of tin (IV) oxide (SnO(2)) thin films deposited by radio-frequency (RF) magnetron sputtering.	stannic oxide	55-69	strawberry notch homolog 1	Homo sapiens	71-74
20839786-2	2010	The 100 nm thick nanofilm is derived from the polyvinylpyrrolidone-hosted SnO(2)/ZnO nanofibers electrospun on the top of ZnO NW arrays via methanol vapor treatment followed by high-temperature calcination.	Povidone	46-66	strawberry notch homolog 1	Homo sapiens	74-77
20875563-1	2010	In this study, SnO(2) nanoparticles (SNPs)-poly(vinylferrocenium) (PVF(+)) modified single-use graphite electrodes were developed for electrochemical monitoring of DNA hybridization.	polyvinylferrocenium	43-64	strawberry notch homolog 1	Homo sapiens	15-18
20875563-1	2010	In this study, SnO(2) nanoparticles (SNPs)-poly(vinylferrocenium) (PVF(+)) modified single-use graphite electrodes were developed for electrochemical monitoring of DNA hybridization.	Graphite	95-103	strawberry notch homolog 1	Homo sapiens	15-18
21230928-1	2010	We discovered that under pressure SnO with alpha-PbO structure, the same structure as in many Fe-based superconductors, e.g., beta-FeSe, undergoes a transition to a superconducting state for p 6 GPa with a maximum Tc of 1.4 K at p=9.3 GPa.	alpha-pbo	43-52	strawberry notch homolog 1	Homo sapiens	34-37
21230928-1	2010	We discovered that under pressure SnO with alpha-PbO structure, the same structure as in many Fe-based superconductors, e.g., beta-FeSe, undergoes a transition to a superconducting state for p 6 GPa with a maximum Tc of 1.4 K at p=9.3 GPa.	Iron	94-96	strawberry notch homolog 1	Homo sapiens	34-37
21230928-1	2010	We discovered that under pressure SnO with alpha-PbO structure, the same structure as in many Fe-based superconductors, e.g., beta-FeSe, undergoes a transition to a superconducting state for p 6 GPa with a maximum Tc of 1.4 K at p=9.3 GPa.	Technetium	214-216	strawberry notch homolog 1	Homo sapiens	34-37
21230928-3	2010	It is further shown from band structure calculations that SnO under pressure exhibits a Fermi surface topology similar to that reported for some Fe-based superconductors and that the nesting between the hole and electron pockets correlates with the change of Tc as a function of pressure.	Iron	88-90	strawberry notch homolog 1	Homo sapiens	58-61
21230928-3	2010	It is further shown from band structure calculations that SnO under pressure exhibits a Fermi surface topology similar to that reported for some Fe-based superconductors and that the nesting between the hole and electron pockets correlates with the change of Tc as a function of pressure.	Technetium	259-261	strawberry notch homolog 1	Homo sapiens	58-61
20689879-1	2010	Highly oriented SnO(2) nanotubes and nanowires arrays have been selectively fabricated via a convenient one-step wet-chemical approach using anodic aluminium oxide (AAO) as a hard template.	Aluminum Oxide	148-163	strawberry notch homolog 1	Homo sapiens	16-19
20820686-1	2010	In this work, we synthesized alpha-Fe(2)O(3)@SnO(2) core-shell structure nanotubes by a facile two-step hydrothermal method for selective enrichment of phosphopeptides.	alpha-fe(2)o(3)	29-44	strawberry notch homolog 1	Homo sapiens	45-48
20820686-3	2010	SnO(2) nanoparticles with an average crystallite size of around 5 nm form a layer of about 10 nm on both walls of the alpha-Fe(2)O(3) nanotubes.	alpha-fe(2)o(3)	118-133	strawberry notch homolog 1	Homo sapiens	0-3
20820686-4	2010	To demonstrate their ability for selective enrichment of phosphopeptides, we applied alpha-Fe(2)O(3)@SnO(2) nanotubes to the isolation and enrichment of the phosphopeptides from standard protein digestion and real samples.	alpha-fe(2)o	85-97	strawberry notch homolog 1	Homo sapiens	101-104
20820686-6	2010	Experiment results demonstrate that SnO(2) coated alpha-Fe(2)O(3) nanotubes show excellent potential for selective enrichment of phosphopeptides.	alpha-fe(2)o	50-62	strawberry notch homolog 1	Homo sapiens	36-39
20431207-0	2010	H(2) sensing characteristics of SnO(2) coated single wall carbon nanotube network sensors.	h(2)	0-4	strawberry notch homolog 1	Homo sapiens	32-35
20647628-1	2010	A novel experimental approach is used for studying the response of ethanol-suspended SnO(2) nanobelts under the influence of low frequency ac electric fields.	Ethanol	67-74	strawberry notch homolog 1	Homo sapiens	85-88
20647628-5	2010	Additional experiments, performed in a parallel plate electrode configuration in a fluidic channel to investigate the effect of dc and very low frequency ac (approximately Hz) electric fields, indicate the presence of electrophoresis in the ethanol-suspended SnO(2) nanobelts.	Ethanol	241-248	strawberry notch homolog 1	Homo sapiens	259-262
20585175-0	2010	Synthesis of Sn doped CuO nanotubes from core-shell Cu/SnO(2) nanowires by the Kirkendall effect.	cupric oxide	22-25	strawberry notch homolog 1	Homo sapiens	55-58
20585175-0	2010	Synthesis of Sn doped CuO nanotubes from core-shell Cu/SnO(2) nanowires by the Kirkendall effect.	Copper	22-24	strawberry notch homolog 1	Homo sapiens	55-58
20585175-2	2010	The Cu/SnO(2) core-shell nanowires were sequentially electrodeposited by forming a SnO(2) shell followed by electrodeposition of the Cu core.	Copper	4-6	strawberry notch homolog 1	Homo sapiens	83-86
20516577-3	2010	Combined ZnO:SnO(2) nanowire arrays yield a desired emission color from (0.30, 0.31) to (0.35, 0.37) and a white luminescence of approximately 100 cd m(-2), whose reproducibility can be controlled accurately.	Zinc Oxide	9-12	strawberry notch homolog 1	Homo sapiens	13-16
20453289-1	2010	ZnO nanorods containing different hollow structures have been grown by a thermal evaporation-deposition method with a mixture of ZnS and SnO(2) powders as precursor.	Zinc Oxide	0-3	strawberry notch homolog 1	Homo sapiens	137-140
20589285-0	2010	Strong electrochemiluminescence based on electron transfer between Tris(2,2"-bipyridine)ruthenium(III) and SnO NPs@MWCNTs.	tris(2,2"-bipyridine)ruthenium	67-97	strawberry notch homolog 1	Homo sapiens	107-110
20589285-1	2010	Strong electrochemiluminescence signals caused by the highly effective electron transfer process between SnO nanoparticles-deposited multiwall carbon nanotubes (SnO NPs@MWCNTs) composite and Ru(bpy)(3)(3+) were observed.	Carbon	143-149	strawberry notch homolog 1	Homo sapiens	105-108
20589285-1	2010	Strong electrochemiluminescence signals caused by the highly effective electron transfer process between SnO nanoparticles-deposited multiwall carbon nanotubes (SnO NPs@MWCNTs) composite and Ru(bpy)(3)(3+) were observed.	Carbon	143-149	strawberry notch homolog 1	Homo sapiens	161-164
20498522-1	2010	A novel method is developed to fabricate a SnO(2) nanotube network by utilizing electrospinning and atomic layer deposition (ALD), and the network sensor is proven to exhibit excellent sensitivity to ethanol owing to its hollow, nanostructured character.	Ethanol	200-207	strawberry notch homolog 1	Homo sapiens	43-46
20498522-2	2010	The electrospun polyacrylonitrile (PAN) nanofibers of 100-200 nm diameter are used as a template after stabilization at 250 degrees C. An uniform and conformal SnO(2) coating on the nanofiber template is achieved by ALD using dibutyltindiacetate (DBTDA) as the Sn source at 100 degrees C and the wall thickness is precisely controlled by adjusting the number of ALD cycles.	polyacrylonitrile	16-33	strawberry notch homolog 1	Homo sapiens	160-163
20498522-2	2010	The electrospun polyacrylonitrile (PAN) nanofibers of 100-200 nm diameter are used as a template after stabilization at 250 degrees C. An uniform and conformal SnO(2) coating on the nanofiber template is achieved by ALD using dibutyltindiacetate (DBTDA) as the Sn source at 100 degrees C and the wall thickness is precisely controlled by adjusting the number of ALD cycles.	dibutyltin diacetate	226-245	strawberry notch homolog 1	Homo sapiens	160-163
20498522-2	2010	The electrospun polyacrylonitrile (PAN) nanofibers of 100-200 nm diameter are used as a template after stabilization at 250 degrees C. An uniform and conformal SnO(2) coating on the nanofiber template is achieved by ALD using dibutyltindiacetate (DBTDA) as the Sn source at 100 degrees C and the wall thickness is precisely controlled by adjusting the number of ALD cycles.	dibutyltin diacetate	247-252	strawberry notch homolog 1	Homo sapiens	160-163
20498522-4	2010	The SnO(2) nanotube network sensor responds to ethanol, H(2), CO, NH(3) and NO(2) gases, but it exhibited an extremely high gas response to ethanol with a short response time (&lt;5 s).	Ethanol	47-54	strawberry notch homolog 1	Homo sapiens	4-7
20498522-4	2010	The SnO(2) nanotube network sensor responds to ethanol, H(2), CO, NH(3) and NO(2) gases, but it exhibited an extremely high gas response to ethanol with a short response time (&lt;5 s).	h(2)	56-60	strawberry notch homolog 1	Homo sapiens	4-7
20498522-4	2010	The SnO(2) nanotube network sensor responds to ethanol, H(2), CO, NH(3) and NO(2) gases, but it exhibited an extremely high gas response to ethanol with a short response time (&lt;5 s).	Carbon Monoxide	62-64	strawberry notch homolog 1	Homo sapiens	4-7
20498522-4	2010	The SnO(2) nanotube network sensor responds to ethanol, H(2), CO, NH(3) and NO(2) gases, but it exhibited an extremely high gas response to ethanol with a short response time (&lt;5 s).	Ammonia	66-71	strawberry notch homolog 1	Homo sapiens	4-7
20498522-4	2010	The SnO(2) nanotube network sensor responds to ethanol, H(2), CO, NH(3) and NO(2) gases, but it exhibited an extremely high gas response to ethanol with a short response time (&lt;5 s).	Ethanol	140-147	strawberry notch homolog 1	Homo sapiens	4-7
20496870-0	2010	Improvement of phase stability and accurate determination of optical constants of SnO thin films by using Al2O3 capping layer.	Aluminum Oxide	106-111	strawberry notch homolog 1	Homo sapiens	82-85
20496870-1	2010	In this letter, it is proposed that the usage of Al(2)O(3) capping layer can tremendously improve the phase stability of SnO thin films, which allows the accurate determination of the optical constants of the SnO films without the perturbation arising from impurity phases.	Aluminum Oxide	49-58	strawberry notch homolog 1	Homo sapiens	121-124
20496870-1	2010	In this letter, it is proposed that the usage of Al(2)O(3) capping layer can tremendously improve the phase stability of SnO thin films, which allows the accurate determination of the optical constants of the SnO films without the perturbation arising from impurity phases.	Aluminum Oxide	49-58	strawberry notch homolog 1	Homo sapiens	209-212
20219206-1	2010	Fluorine-doped tin dioxide (FTO) nanocrystals were prepared with a sol-gel process followed by a hydrothermal treatment using SnCl(4) and NH(4)F as SnO(2) and fluorine dopant, respectively.	Fluorine	0-8	strawberry notch homolog 1	Homo sapiens	148-151
20219206-1	2010	Fluorine-doped tin dioxide (FTO) nanocrystals were prepared with a sol-gel process followed by a hydrothermal treatment using SnCl(4) and NH(4)F as SnO(2) and fluorine dopant, respectively.	stannic oxide	15-26	strawberry notch homolog 1	Homo sapiens	148-151
20219206-1	2010	Fluorine-doped tin dioxide (FTO) nanocrystals were prepared with a sol-gel process followed by a hydrothermal treatment using SnCl(4) and NH(4)F as SnO(2) and fluorine dopant, respectively.	L 685458	28-31	strawberry notch homolog 1	Homo sapiens	148-151
20219206-3	2010	The diameter of the fluorine doped SnO(2) nanocrystal in rutile-type structure is about 10nm.	Fluorine	20-28	strawberry notch homolog 1	Homo sapiens	35-38
20219206-4	2010	Compared to the pure SnO(2) nanocrystals, the fluorine doped SnO(2) nanocrystals can be dispersed homogeneously in H(2)O, forming transparent sol with high stability.	Fluorine	46-54	strawberry notch homolog 1	Homo sapiens	21-24
20219206-6	2010	The results show that sheet resistances (Rs) of fluorine doped SnO(2) decrease with the increasing NH(4)F/Sn molar ratio in the range from 0 to 2.	Fluorine	48-56	strawberry notch homolog 1	Homo sapiens	63-66
20219206-8	2010	The F/Sn molar ratio of fluorine doped SnO(2) measured by XPS is about 0.18 when NH(4)F/Sn molar ratio is equal to 2, and the sheet resistance of fluorine doped SnO(2) powder is 110Omega/ .	Fluorine	24-32	strawberry notch homolog 1	Homo sapiens	39-42
20219206-8	2010	The F/Sn molar ratio of fluorine doped SnO(2) measured by XPS is about 0.18 when NH(4)F/Sn molar ratio is equal to 2, and the sheet resistance of fluorine doped SnO(2) powder is 110Omega/ .	Fluorine	24-32	strawberry notch homolog 1	Homo sapiens	161-164
20219206-8	2010	The F/Sn molar ratio of fluorine doped SnO(2) measured by XPS is about 0.18 when NH(4)F/Sn molar ratio is equal to 2, and the sheet resistance of fluorine doped SnO(2) powder is 110Omega/ .	Fluorine	146-154	strawberry notch homolog 1	Homo sapiens	39-42
20219206-8	2010	The F/Sn molar ratio of fluorine doped SnO(2) measured by XPS is about 0.18 when NH(4)F/Sn molar ratio is equal to 2, and the sheet resistance of fluorine doped SnO(2) powder is 110Omega/ .	Fluorine	146-154	strawberry notch homolog 1	Homo sapiens	161-164
20499979-1	2010	CeO(2)-SnO(2) solid solution has been reported to possess high oxygen storage/release property which possibly originates from local structural distortion.	Oxygen	63-69	strawberry notch homolog 1	Homo sapiens	7-10
20499979-4	2010	An analysis of local structural distortions reflected in phonon dispersion show that SnO(2) in fluorite structure is highly unstable while CeO(2) in rutile structure is only weakly unstable.	Calcium Fluoride	95-103	strawberry notch homolog 1	Homo sapiens	85-88
20431207-0	2010	H(2) sensing characteristics of SnO(2) coated single wall carbon nanotube network sensors.	Carbon	58-64	strawberry notch homolog 1	Homo sapiens	32-35
20431207-1	2010	SnO(2) nanoparticle coated single wall nanotube (SWNT) network sensors were fabricated by forming a SWNT network on the Pt patterned SiO(2)/Si substrate using a dip coating method and subsequently depositing SnO(2) nanoparticles on the SWNT network by rf magnetron sputtering.	Silicon Dioxide	133-139	strawberry notch homolog 1	Homo sapiens	0-3
20431207-1	2010	SnO(2) nanoparticle coated single wall nanotube (SWNT) network sensors were fabricated by forming a SWNT network on the Pt patterned SiO(2)/Si substrate using a dip coating method and subsequently depositing SnO(2) nanoparticles on the SWNT network by rf magnetron sputtering.	Silicon	133-135	strawberry notch homolog 1	Homo sapiens	0-3
20431207-1	2010	SnO(2) nanoparticle coated single wall nanotube (SWNT) network sensors were fabricated by forming a SWNT network on the Pt patterned SiO(2)/Si substrate using a dip coating method and subsequently depositing SnO(2) nanoparticles on the SWNT network by rf magnetron sputtering.	3,5-diisopropylsalicylic acid	161-164	strawberry notch homolog 1	Homo sapiens	0-3
20431207-3	2010	The SnO(2)-SWNT network sensors stably and reversibly responded to H(2) gas even at room temperature and could detect H(2) gas down to 100 ppm.	h(2)	67-71	strawberry notch homolog 1	Homo sapiens	4-7
20431207-3	2010	The SnO(2)-SWNT network sensors stably and reversibly responded to H(2) gas even at room temperature and could detect H(2) gas down to 100 ppm.	h(2)	118-122	strawberry notch homolog 1	Homo sapiens	4-7
20449353-0	2010	Bidimensional versus tridimensional oxygen vacancy diffusion in SnO(2-x) under different gas environments.	Oxygen	36-42	strawberry notch homolog 1	Homo sapiens	64-67
20302336-5	2010	We investigate the influence of treating the surface of the SnO(2) with different oxides and find that MgO "passivated" SnO(2) electrodes demonstrate an unprecedented absorbed photon-to-electron conversion efficiency of near unity across a broad spectral range.	Magnesium Oxide	103-106	strawberry notch homolog 1	Homo sapiens	60-63
20302336-5	2010	We investigate the influence of treating the surface of the SnO(2) with different oxides and find that MgO "passivated" SnO(2) electrodes demonstrate an unprecedented absorbed photon-to-electron conversion efficiency of near unity across a broad spectral range.	Magnesium Oxide	103-106	strawberry notch homolog 1	Homo sapiens	120-123
20423126-1	2010	A simple, cost-effective, two-step method was proposed for preparing single-phase SnO polycrystalline thin films on quartz.	polycrystalline	86-101	strawberry notch homolog 1	Homo sapiens	82-85
20201521-7	2010	Although fewer peptides were identified using stannia, the complementarity of SnO(2)-based MOAC could be shown as more than 140 phosphopeptides were exclusively identified by this material.	moac	91-95	strawberry notch homolog 1	Homo sapiens	78-81
22557364-4	2010	XRD peaks of Vanga Bhasma are identified to be as Tindioxide (SnO(2)).	stannic oxide	50-60	strawberry notch homolog 1	Homo sapiens	62-65
20183815-1	2010	Tin monoxide (SnO) nanosheets 5 nm in thickness are generated on substrates through an aqueous solution process under mild conditions.	Tin(II) oxide	0-12	strawberry notch homolog 1	Homo sapiens	14-17
20183815-3	2010	The SnO nanosheets form a porous thin film on substrates such as indium tin oxide and carbon nanofiber (CNF).	indium tin oxide	65-81	strawberry notch homolog 1	Homo sapiens	4-7
20183815-3	2010	The SnO nanosheets form a porous thin film on substrates such as indium tin oxide and carbon nanofiber (CNF).	Carbon	86-92	strawberry notch homolog 1	Homo sapiens	4-7
20183815-6	2010	Composites of the SnO nanosheets and CNF perform as the anode material of lithium-ion batteries with improved charge-discharge reversible stability.	Lithium	74-81	strawberry notch homolog 1	Homo sapiens	18-21
20449353-3	2010	Experimentally, the electrical resistance of individual metal oxide SnO(2-x) nanowires shows modulation: when the environment is oxygen rich long term drifts (hours) are observed indicating extended vacancy dynamics.	metal oxide	56-67	strawberry notch homolog 1	Homo sapiens	68-71
20449353-3	2010	Experimentally, the electrical resistance of individual metal oxide SnO(2-x) nanowires shows modulation: when the environment is oxygen rich long term drifts (hours) are observed indicating extended vacancy dynamics.	Oxygen	129-135	strawberry notch homolog 1	Homo sapiens	68-71
20449353-6	2010	For oxygen-poor environments, oxygen vacancy excorporation and healing are confined to the near-surface layer of SnO(2-x) (bidimensional or near-surface diffusion), and completed in short times.	Oxygen	4-10	strawberry notch homolog 1	Homo sapiens	113-116
20449353-6	2010	For oxygen-poor environments, oxygen vacancy excorporation and healing are confined to the near-surface layer of SnO(2-x) (bidimensional or near-surface diffusion), and completed in short times.	Oxygen	30-36	strawberry notch homolog 1	Homo sapiens	113-116
20078069-4	2010	Significantly, some of the SnO(2)/alpha-Fe(2)O(3) SNHs exhibited excellent visible light or UV photocatalytic abilities, remarkably superior to their alpha-Fe(2)O(3) precursors, mainly owing to the effective electron-hole separation at the SnO(2)/alpha-Fe(2)O(3) interfaces.	alpha-fe(2)o	34-46	strawberry notch homolog 1	Homo sapiens	27-30
20063879-1	2010	Hierarchical SnO(2) microspheres consisting of nanosheets on the fluorine-doped tin oxide (FTO) glass substrates are successfully prepared via a facile hydrothermal synthesis process.	Fluorine	65-73	strawberry notch homolog 1	Homo sapiens	13-16
20063879-1	2010	Hierarchical SnO(2) microspheres consisting of nanosheets on the fluorine-doped tin oxide (FTO) glass substrates are successfully prepared via a facile hydrothermal synthesis process.	stannic oxide	80-89	strawberry notch homolog 1	Homo sapiens	13-16
20063879-1	2010	Hierarchical SnO(2) microspheres consisting of nanosheets on the fluorine-doped tin oxide (FTO) glass substrates are successfully prepared via a facile hydrothermal synthesis process.	L 685458	91-94	strawberry notch homolog 1	Homo sapiens	13-16
20063879-3	2010	Moreover, SnO(2) nanoparticles with 30-80 nm in size covered on the surface of nanosheets/microspheres were also obtained by optimizing the hydrothermal reaction temperature, time, or volume ratio of acetylacetone/H(2)O.	acetylacetone	200-213	strawberry notch homolog 1	Homo sapiens	10-13
20063879-4	2010	The detailed investigations disclose the experimental parameters, such as acetylacetone, NH(4)F, and seed layer play important roles in the morphology of hierarchical SnO(2) microspheres on the FTO glass.	acetylacetone	74-87	strawberry notch homolog 1	Homo sapiens	167-170
20078069-4	2010	Significantly, some of the SnO(2)/alpha-Fe(2)O(3) SNHs exhibited excellent visible light or UV photocatalytic abilities, remarkably superior to their alpha-Fe(2)O(3) precursors, mainly owing to the effective electron-hole separation at the SnO(2)/alpha-Fe(2)O(3) interfaces.	alpha-fe(2)o	34-46	strawberry notch homolog 1	Homo sapiens	240-243
20078069-4	2010	Significantly, some of the SnO(2)/alpha-Fe(2)O(3) SNHs exhibited excellent visible light or UV photocatalytic abilities, remarkably superior to their alpha-Fe(2)O(3) precursors, mainly owing to the effective electron-hole separation at the SnO(2)/alpha-Fe(2)O(3) interfaces.	fe(2)o	40-46	strawberry notch homolog 1	Homo sapiens	27-30
20078069-4	2010	Significantly, some of the SnO(2)/alpha-Fe(2)O(3) SNHs exhibited excellent visible light or UV photocatalytic abilities, remarkably superior to their alpha-Fe(2)O(3) precursors, mainly owing to the effective electron-hole separation at the SnO(2)/alpha-Fe(2)O(3) interfaces.	fe(2)o	40-46	strawberry notch homolog 1	Homo sapiens	240-243
20078069-4	2010	Significantly, some of the SnO(2)/alpha-Fe(2)O(3) SNHs exhibited excellent visible light or UV photocatalytic abilities, remarkably superior to their alpha-Fe(2)O(3) precursors, mainly owing to the effective electron-hole separation at the SnO(2)/alpha-Fe(2)O(3) interfaces.	alpha-fe(2)o	150-162	strawberry notch homolog 1	Homo sapiens	27-30
19957984-1	2010	We present a detailed investigation on the optical properties, including dielectric function, reflectivity, absorption, refractive index, and electron energy-loss spectrum, of the high-pressure phase SnO(2) in the rutile, pyrite, fluorite, and cotunnite structures by using the density functional theory (DFT) plane-wave pseudopotential method.	Calcium Fluoride	230-238	strawberry notch homolog 1	Homo sapiens	200-203
20057026-1	2010	Abnormal gas sensing characteristics are observed at low temperature in uniformly loaded Pt@SnO(2) nanorod gas sensors.	Platinum	89-91	strawberry notch homolog 1	Homo sapiens	92-95
20062882-0	2010	Nanoscale Si coating on the pore walls of SnO(2) nanotube anode for Li rechargeable batteries.	Silicon	10-12	strawberry notch homolog 1	Homo sapiens	42-45
20062882-1	2010	A nanoscale coating of a Si layer on the pore walls of SnO(2) nanotubes (Si-coated SnO(2)) leads to very good electrochemical performance in coulombic efficiency, rate capability and capacity retention compared with untreated SnO(2) nanotubes.	Silicon	25-27	strawberry notch homolog 1	Homo sapiens	55-58
20062882-1	2010	A nanoscale coating of a Si layer on the pore walls of SnO(2) nanotubes (Si-coated SnO(2)) leads to very good electrochemical performance in coulombic efficiency, rate capability and capacity retention compared with untreated SnO(2) nanotubes.	Silicon	25-27	strawberry notch homolog 1	Homo sapiens	83-86
20062882-1	2010	A nanoscale coating of a Si layer on the pore walls of SnO(2) nanotubes (Si-coated SnO(2)) leads to very good electrochemical performance in coulombic efficiency, rate capability and capacity retention compared with untreated SnO(2) nanotubes.	Silicon	25-27	strawberry notch homolog 1	Homo sapiens	83-86
20062882-1	2010	A nanoscale coating of a Si layer on the pore walls of SnO(2) nanotubes (Si-coated SnO(2)) leads to very good electrochemical performance in coulombic efficiency, rate capability and capacity retention compared with untreated SnO(2) nanotubes.	Silicon	73-75	strawberry notch homolog 1	Homo sapiens	55-58
20062882-1	2010	A nanoscale coating of a Si layer on the pore walls of SnO(2) nanotubes (Si-coated SnO(2)) leads to very good electrochemical performance in coulombic efficiency, rate capability and capacity retention compared with untreated SnO(2) nanotubes.	Silicon	73-75	strawberry notch homolog 1	Homo sapiens	83-86
20062882-1	2010	A nanoscale coating of a Si layer on the pore walls of SnO(2) nanotubes (Si-coated SnO(2)) leads to very good electrochemical performance in coulombic efficiency, rate capability and capacity retention compared with untreated SnO(2) nanotubes.	Silicon	73-75	strawberry notch homolog 1	Homo sapiens	83-86
20672094-0	2010	Carbon-Coated SnO(2) Nanorod Array for Lithium-Ion Battery Anode Material.	Carbon	0-6	strawberry notch homolog 1	Homo sapiens	14-17
20672094-0	2010	Carbon-Coated SnO(2) Nanorod Array for Lithium-Ion Battery Anode Material.	Lithium	39-46	strawberry notch homolog 1	Homo sapiens	14-17
20672094-1	2010	Carbon-coated SnO(2) nanorod array directly grown on the substrate has been prepared by a two-step hydrothermal method for anode material of lithium-ion batteries (LIBs).	Carbon	0-6	strawberry notch homolog 1	Homo sapiens	14-17
20672094-1	2010	Carbon-coated SnO(2) nanorod array directly grown on the substrate has been prepared by a two-step hydrothermal method for anode material of lithium-ion batteries (LIBs).	Lithium	141-148	strawberry notch homolog 1	Homo sapiens	14-17
19957984-1	2010	We present a detailed investigation on the optical properties, including dielectric function, reflectivity, absorption, refractive index, and electron energy-loss spectrum, of the high-pressure phase SnO(2) in the rutile, pyrite, fluorite, and cotunnite structures by using the density functional theory (DFT) plane-wave pseudopotential method.	cotunnite	244-253	strawberry notch homolog 1	Homo sapiens	200-203
20672094-1	2010	Carbon-coated SnO(2) nanorod array directly grown on the substrate has been prepared by a two-step hydrothermal method for anode material of lithium-ion batteries (LIBs).	libs	164-168	strawberry notch homolog 1	Homo sapiens	14-17
19962341-0	2010	DNA cleavage, antimicrobial, spectroscopic and fluorescence studies of Co(II), Ni(II) and Cu(II) complexes with SNO donor coumarin Schiff bases.	Cobalt(2+)	71-77	strawberry notch homolog 1	Homo sapiens	112-115
19962341-0	2010	DNA cleavage, antimicrobial, spectroscopic and fluorescence studies of Co(II), Ni(II) and Cu(II) complexes with SNO donor coumarin Schiff bases.	Nickel(2+)	79-85	strawberry notch homolog 1	Homo sapiens	112-115
19962341-0	2010	DNA cleavage, antimicrobial, spectroscopic and fluorescence studies of Co(II), Ni(II) and Cu(II) complexes with SNO donor coumarin Schiff bases.	cu(ii)	90-96	strawberry notch homolog 1	Homo sapiens	112-115
19962341-0	2010	DNA cleavage, antimicrobial, spectroscopic and fluorescence studies of Co(II), Ni(II) and Cu(II) complexes with SNO donor coumarin Schiff bases.	coumarin schiff bases	122-143	strawberry notch homolog 1	Homo sapiens	112-115
19923652-3	2009	In this study, silatrane-functionalized dyes and analogous carboxylate-functionalized dyes were used as visible light sensitizers for porous nanoparticulate SnO(2) photoanodes.	silatrane	15-24	strawberry notch homolog 1	Homo sapiens	157-160
19943259-0	2010	Morphology-controlled synthesis of SnO(2) nanotubes by using 1D silica mesostructures as sacrificial templates and their applications in lithium-ion batteries.	Silicon Dioxide	64-70	strawberry notch homolog 1	Homo sapiens	35-38
19943259-0	2010	Morphology-controlled synthesis of SnO(2) nanotubes by using 1D silica mesostructures as sacrificial templates and their applications in lithium-ion batteries.	Lithium	137-144	strawberry notch homolog 1	Homo sapiens	35-38
19943259-1	2010	SnO(2) nanotubes with controllable morphologies are successfully synthesized by using a variety of one-dimensional (1D) silica mesostructures as effective sacrificial templates.	Silicon Dioxide	120-126	strawberry notch homolog 1	Homo sapiens	0-3
19943259-3	2010	Subsequently, the obtained 1D silica mesostructures are used as sacrificial templates to synthesize SnO(2) nanotubes with preserved morphologies via a simple hydrothermal route, resulting in the formation of well-defined SnO(2) nanotubes with different lengths and unique helical SnO(2) nanotubes with a wealth of conformations.	Silicon Dioxide	30-36	strawberry notch homolog 1	Homo sapiens	100-103
19943259-3	2010	Subsequently, the obtained 1D silica mesostructures are used as sacrificial templates to synthesize SnO(2) nanotubes with preserved morphologies via a simple hydrothermal route, resulting in the formation of well-defined SnO(2) nanotubes with different lengths and unique helical SnO(2) nanotubes with a wealth of conformations.	Silicon Dioxide	30-36	strawberry notch homolog 1	Homo sapiens	221-224
19943259-3	2010	Subsequently, the obtained 1D silica mesostructures are used as sacrificial templates to synthesize SnO(2) nanotubes with preserved morphologies via a simple hydrothermal route, resulting in the formation of well-defined SnO(2) nanotubes with different lengths and unique helical SnO(2) nanotubes with a wealth of conformations.	Silicon Dioxide	30-36	strawberry notch homolog 1	Homo sapiens	221-224
19943259-4	2010	It is revealed that both of the short and long SnO(2) nanotubes showed much better performance as anode materials in lithium-ion batteries than normal SnO(2) nanopowders, which might be related to the hollow structure of the nanotubes that could alleviate the volume changes and mechanical stress during charging/discharging cycling.	Lithium	117-124	strawberry notch homolog 1	Homo sapiens	47-50
22163564-1	2010	This study is an investigation of high-humidity aging effects on the total volatile organic compound (T-VOC) gas-sensing properties of platinum, palladium, and gold-loaded tin oxide (Pt,Pd,Au/SnO(2)) thick films.	Platinum	135-143	strawberry notch homolog 1	Homo sapiens	192-195
22163564-1	2010	This study is an investigation of high-humidity aging effects on the total volatile organic compound (T-VOC) gas-sensing properties of platinum, palladium, and gold-loaded tin oxide (Pt,Pd,Au/SnO(2)) thick films.	stannic oxide	172-181	strawberry notch homolog 1	Homo sapiens	192-195
22163564-3	2010	The high-humidity aging is an effective treatment for resistance to humidity change for the Pt,Pd,Au/SnO(2) but not effective for the Pt/SnO(2).	Platinum	92-94	strawberry notch homolog 1	Homo sapiens	101-104
22163586-0	2010	The effects of the location of Au additives on combustion-generated SnO(2) nanopowders for CO gas sensing.	Gold	31-33	strawberry notch homolog 1	Homo sapiens	68-71
22163586-1	2010	The current work presents the results of an experimental study of the effects of the location of gold additives on the performance of combustion-generated tin dioxide (SnO(2)) nanopowders in solid state gas sensors.	stannic oxide	155-166	strawberry notch homolog 1	Homo sapiens	168-171
22163586-2	2010	The time response and sensor response to 500 ppm carbon monoxide is reported for a range of gold additive/SnO(2) film architectures including the use of colloidal, sputtered, and combustion-generated Au additives.	Carbon Monoxide	49-64	strawberry notch homolog 1	Homo sapiens	106-109
19923652-3	2009	In this study, silatrane-functionalized dyes and analogous carboxylate-functionalized dyes were used as visible light sensitizers for porous nanoparticulate SnO(2) photoanodes.	carboxylate	59-70	strawberry notch homolog 1	Homo sapiens	157-160
19923652-3	2009	In this study, silatrane-functionalized dyes and analogous carboxylate-functionalized dyes were used as visible light sensitizers for porous nanoparticulate SnO(2) photoanodes.	photoanodes	164-175	strawberry notch homolog 1	Homo sapiens	157-160
19772329-0	2009	Hierarchical assembly of ZnO nanostructures on SnO(2) backbone nanowires: low-temperature hydrothermal preparation and optical properties.	Zinc Oxide	25-28	strawberry notch homolog 1	Homo sapiens	47-50
19822150-1	2009	Herein, we report that dihydrolipoic acid and lipoic acid (LA) plus lipoamide dehydrogenase and NADH denitrosate S-nitrosocaspase 3 (CASP-SNO).	dihydrolipoic acid	23-41	strawberry notch homolog 1	Homo sapiens	138-141
19822150-1	2009	Herein, we report that dihydrolipoic acid and lipoic acid (LA) plus lipoamide dehydrogenase and NADH denitrosate S-nitrosocaspase 3 (CASP-SNO).	Thioctic Acid	30-41	strawberry notch homolog 1	Homo sapiens	138-141
19822150-1	2009	Herein, we report that dihydrolipoic acid and lipoic acid (LA) plus lipoamide dehydrogenase and NADH denitrosate S-nitrosocaspase 3 (CASP-SNO).	nadh denitrosate	96-112	strawberry notch homolog 1	Homo sapiens	138-141
20644851-6	2009	It is found that alpha-Fe(2)O(3)@SnO(2) nanorattles manifest a much lower initial irreversible loss and higher reversible capacity compared to SnO(2) hollow spheres.	alpha-fe(2)o	17-29	strawberry notch homolog 1	Homo sapiens	33-36
19772329-2	2009	The ZnO nanorods grow epitaxially on the SnO(2) nanowire side faces mainly with a four-fold symmetry.	Zinc Oxide	4-7	strawberry notch homolog 1	Homo sapiens	41-44
19772329-5	2009	Such hybrid SnO(2)-ZnO nanostructures show an enhanced near-band gap emission compared with the primary SnO(2) nanowires.	Zinc Oxide	19-22	strawberry notch homolog 1	Homo sapiens	12-15
19772329-5	2009	Such hybrid SnO(2)-ZnO nanostructures show an enhanced near-band gap emission compared with the primary SnO(2) nanowires.	Zinc Oxide	19-22	strawberry notch homolog 1	Homo sapiens	104-107
19670846-4	2009	A sharp transition from green to red emission correlates with a phase transition of beta-Ga(2)O(3) to polycrystalline SnO(2).	beta-ga(2)o	84-95	strawberry notch homolog 1	Homo sapiens	118-121
19705911-1	2009	Double-shelled nanocapsules of V(2)O(5)-SnO(2) composites were chemically assembled via a one-pot solution method.	vanadium pentoxide	31-39	strawberry notch homolog 1	Homo sapiens	40-43
19670846-4	2009	A sharp transition from green to red emission correlates with a phase transition of beta-Ga(2)O(3) to polycrystalline SnO(2).	polycrystalline	102-117	strawberry notch homolog 1	Homo sapiens	118-121
20628463-6	2009	The loading of SnO(2) on the surface of carbon hollow spheres was processed, and its PL property was also characterized.	Carbon	40-46	strawberry notch homolog 1	Homo sapiens	15-18
19652284-0	2009	One-dimensional SnO(2) nanostructures: facile morphology tuning and lithium storage properties.	Lithium	68-75	strawberry notch homolog 1	Homo sapiens	16-19
19652284-1	2009	This paper presents a facile method of preparation whereby one-dimensional SnO(2) nanostructures of different morphologies, namely nanotubes, nanotube-nanorod hybrids and nanorods, could be obtained by thermally treating an alumina template loaded with SnCl(4) aqueous solution in air.	Aluminum Oxide	224-231	strawberry notch homolog 1	Homo sapiens	75-78
19448295-7	2009	The mixture ratio of Zn and Sn was optimized (40% Zn and 25% Sn) to maintain proper hole-electron recombination at the QD layer and avoid the yellowish-white emission from ZnO/SnO(2).	Zinc	21-23	strawberry notch homolog 1	Homo sapiens	176-179
20596286-0	2009	Considerable Enhancement of Field Emission of SnO(2) Nanowires by Post-Annealing Process in Oxygen at High Temperature.	Oxygen	92-98	strawberry notch homolog 1	Homo sapiens	46-49
20596286-3	2009	Considerable enhancement of field emission of SnO(2) nanowires was obtained by a post-annealing process in oxygen at high temperature.	Oxygen	107-113	strawberry notch homolog 1	Homo sapiens	46-49
20596286-4	2009	When the SnO(2) nanowires were post-annealed at 1,000 degrees C in oxygen, the turn-on and threshold field were decreased to 3.77 and 4.4 V/mum, respectively, and the current density was increased to 6.58 from 0.3 mA/cm(2) at the same applied electric field of 5.0 V/mum.	Oxygen	67-73	strawberry notch homolog 1	Homo sapiens	9-12
19448295-7	2009	The mixture ratio of Zn and Sn was optimized (40% Zn and 25% Sn) to maintain proper hole-electron recombination at the QD layer and avoid the yellowish-white emission from ZnO/SnO(2).	Tin	28-30	strawberry notch homolog 1	Homo sapiens	176-179
19448295-7	2009	The mixture ratio of Zn and Sn was optimized (40% Zn and 25% Sn) to maintain proper hole-electron recombination at the QD layer and avoid the yellowish-white emission from ZnO/SnO(2).	Tin	61-63	strawberry notch homolog 1	Homo sapiens	176-179
19405696-4	2009	Here we report a novel method to prepare stoichiometric tin oxide by modifying the known plasma enhanced chemical vapor deposition technique using SnCl(4)-xH(2)O as precursor and O(2) as reactant gas at various temperatures from 300 to 800 degrees C. Tetragonal rutile structure of SnO(2) was found, grown along the [110] direction.	stannic oxide	56-65	strawberry notch homolog 1	Homo sapiens	282-285
19436096-2	2009	The SiNWs were grown using tin and indium as catalysts prepared by in situ H(2) plasma reduction of SnO(2) and ITO substrates, respectively.	Indium	35-41	strawberry notch homolog 1	Homo sapiens	100-103
18799264-0	2009	Preparation and characterization of Ti/SnO(2)-Sb(2)O(3)-Nb(2)O(5)/PbO(2) thin film as electrode material for the degradation of phenol.	(3)-nb(2)	52-61	strawberry notch homolog 1	Homo sapiens	39-42
18799264-0	2009	Preparation and characterization of Ti/SnO(2)-Sb(2)O(3)-Nb(2)O(5)/PbO(2) thin film as electrode material for the degradation of phenol.	Phenol	128-134	strawberry notch homolog 1	Homo sapiens	39-42
18799264-1	2009	In this work, a novel electrode of titanium substrate coated with mixed metal oxides of SnO(2), Sb(2)O(3), Nb(2)O(5) and PbO(2) was successfully prepared using thermal decomposition and electrodeposition.	Titanium	35-43	strawberry notch homolog 1	Homo sapiens	88-91
18799264-1	2009	In this work, a novel electrode of titanium substrate coated with mixed metal oxides of SnO(2), Sb(2)O(3), Nb(2)O(5) and PbO(2) was successfully prepared using thermal decomposition and electrodeposition.	Metals	72-77	strawberry notch homolog 1	Homo sapiens	88-91
19420558-0	2009	Surface doping for photocatalytic purposes: relations between particle size, surface modifications, and photoactivity of SnO(2):Zn2+ nanocrystals.	Zinc	128-132	strawberry notch homolog 1	Homo sapiens	121-124
19420558-5	2009	It is found that Zn(2+) doped SnO(2) showed excellent activity toward photodegradation of methylene blue solution under UV light irradiation.	Zinc	17-19	strawberry notch homolog 1	Homo sapiens	30-33
19420558-5	2009	It is found that Zn(2+) doped SnO(2) showed excellent activity toward photodegradation of methylene blue solution under UV light irradiation.	Methylene Blue	90-104	strawberry notch homolog 1	Homo sapiens	30-33
19420558-6	2009	These observations were interpreted in terms of the Zn(2+) doping at the surface sites of SnO(2) nanoparticles and the relevant defects that have increased the surface active sites and moreover improved the ratio of surface charge carrier transfer rate to the electron-hole recombination rate.	Zinc	52-54	strawberry notch homolog 1	Homo sapiens	90-93
21582666-2	2009	The carboxyl-ate groups are approximately coplanar with the thio-phene ring [dihedral angle = 4.0 (1) ] and the Sn-O bond distance of 2.058 (4) A is comparable to that in related organotin carboxyl-ates.	carboxyl-ates	189-202	strawberry notch homolog 1	Homo sapiens	112-116
19381374-4	2009	DCIP UVB dosimeter films exhibit a response that is related to the irradiance level and duration of UVB exposure, the level of SnO(2) present and to a lesser extent the level of glycerol present.	2,6-Dichloroindophenol	0-4	strawberry notch homolog 1	Homo sapiens	127-130
19298879-3	2009	The preparation of SnO(2) microspheres by the nanocasting technique, using silica of different morphology as a template, offers a strategy to prepare materials that vary in their particle size and their porosity.	Silicon Dioxide	75-81	strawberry notch homolog 1	Homo sapiens	19-22
19124153-4	2009	We found that nitrogen-doped diamond-like carbon (DLC:N) promoted cell attachment relative to other materials tested in the rank order of DLC:N&gt;In(2)O(3)/SnO(2) (ITO), Pt&gt;Au.	Nitrogen	14-22	strawberry notch homolog 1	Homo sapiens	157-160
18586390-1	2009	In the presence of O(3), the oxidative decolorization reaction on molasses fermentation wastewater with SnO(2) as a catalyst was studied.	Ozone	19-23	strawberry notch homolog 1	Homo sapiens	104-107
18586390-4	2009	SnO(2) prepared by ammonia as the precipitant had higher catalytic activity and a stronger dehydroxylation.	Ammonia	19-26	strawberry notch homolog 1	Homo sapiens	0-3
18586390-5	2009	The IR spectra of adsorbed pyridine showed that there were Lewis acid sites on the surface of this SnO(2) catalyst.	pyridine	27-35	strawberry notch homolog 1	Homo sapiens	99-102
18586390-5	2009	The IR spectra of adsorbed pyridine showed that there were Lewis acid sites on the surface of this SnO(2) catalyst.	Lewis Acids	59-69	strawberry notch homolog 1	Homo sapiens	99-102
19334881-6	2009	In particular, a peculiar surface restructuring, involving the formation of a network of SnO(2) species, appears for large oxygen coverage.	Oxygen	123-129	strawberry notch homolog 1	Homo sapiens	89-92
19124153-4	2009	We found that nitrogen-doped diamond-like carbon (DLC:N) promoted cell attachment relative to other materials tested in the rank order of DLC:N&gt;In(2)O(3)/SnO(2) (ITO), Pt&gt;Au.	Carbon	42-48	strawberry notch homolog 1	Homo sapiens	157-160
18950221-1	2008	A novel layer-by-layer approach has been developed to synthesize polycrystalline SnO(2) hollow spheres with tunable shell thickness and size using SiO(2) spheres as a template.	polycrystalline	65-80	strawberry notch homolog 1	Homo sapiens	81-84
19140761-2	2009	Tin oxide nanoparticles (2-5 nm) have been structured using CTAB surfactant into mesoporous mpSnO(2) materials that exhibit lower electrical resistivity than the precursors SnO(2) nanoparticles and over nine orders the magnitude lower than that of mesoporous MCM-41 silica.	stannic oxide	0-9	strawberry notch homolog 1	Homo sapiens	94-97
19140761-3	2009	The superior performance of these conductive mesoporous mpSnO(2) materials as hosts is clearly manifested by the fact that a conjugated polymer with 2,5-dimethoxyphenylenevinylene structure emits light at voltages below 10 V direct current when incorporated in mpSnO(2) materials, but not in analogous mesoporous MCM-41 silica or when adsorbed on the nonporous precursor SnO(2) nanoparticles.	Polymers	136-143	strawberry notch homolog 1	Homo sapiens	58-61
19140761-3	2009	The superior performance of these conductive mesoporous mpSnO(2) materials as hosts is clearly manifested by the fact that a conjugated polymer with 2,5-dimethoxyphenylenevinylene structure emits light at voltages below 10 V direct current when incorporated in mpSnO(2) materials, but not in analogous mesoporous MCM-41 silica or when adsorbed on the nonporous precursor SnO(2) nanoparticles.	2,5-dimethoxyphenylenevinylene	149-179	strawberry notch homolog 1	Homo sapiens	58-61
19140761-3	2009	The superior performance of these conductive mesoporous mpSnO(2) materials as hosts is clearly manifested by the fact that a conjugated polymer with 2,5-dimethoxyphenylenevinylene structure emits light at voltages below 10 V direct current when incorporated in mpSnO(2) materials, but not in analogous mesoporous MCM-41 silica or when adsorbed on the nonporous precursor SnO(2) nanoparticles.	mpsno	261-266	strawberry notch homolog 1	Homo sapiens	58-61
19140761-3	2009	The superior performance of these conductive mesoporous mpSnO(2) materials as hosts is clearly manifested by the fact that a conjugated polymer with 2,5-dimethoxyphenylenevinylene structure emits light at voltages below 10 V direct current when incorporated in mpSnO(2) materials, but not in analogous mesoporous MCM-41 silica or when adsorbed on the nonporous precursor SnO(2) nanoparticles.	mesoporous	45-55	strawberry notch homolog 1	Homo sapiens	58-61
19140761-3	2009	The superior performance of these conductive mesoporous mpSnO(2) materials as hosts is clearly manifested by the fact that a conjugated polymer with 2,5-dimethoxyphenylenevinylene structure emits light at voltages below 10 V direct current when incorporated in mpSnO(2) materials, but not in analogous mesoporous MCM-41 silica or when adsorbed on the nonporous precursor SnO(2) nanoparticles.	Silicon Dioxide	320-326	strawberry notch homolog 1	Homo sapiens	58-61
19417318-4	2009	The sensor response is up to 19.6 under 10 ppm ethanol exposure at 220 degrees C. Both the response time and the recovery time of the core-shell structures are less than 30 s. Based on the space-charge layer model and semiconductor heterojunction theory, the small thickness of the SnO(2) shell and the formation of heterojunctions contribute to the enhanced ethanol sensing characteristics.	Ethanol	47-54	strawberry notch homolog 1	Homo sapiens	282-285
22291557-5	2009	Some of the films are highly sensitive to low concentrations of H(2)S (10 ppm) at low operating temperatures (100 and 200  C) and the best response in terms of R(air)/R(gas) is given by Cu-SnO(2) films (2500) followed by WO(3) (1200) and In(2)O(3) (75).	Hydrogen Sulfide	64-69	strawberry notch homolog 1	Homo sapiens	189-192
22291557-5	2009	Some of the films are highly sensitive to low concentrations of H(2)S (10 ppm) at low operating temperatures (100 and 200  C) and the best response in terms of R(air)/R(gas) is given by Cu-SnO(2) films (2500) followed by WO(3) (1200) and In(2)O(3) (75).	Copper	186-188	strawberry notch homolog 1	Homo sapiens	189-192
22454597-6	2009	It mainly focuses on the metal oxide 1D nanostructures such as ZnO, SnO(2), Cu(2)O, Ga(2)O(3), Fe(2)O(3), In(2)O(3), CdO, CeO(2), and their photoresponses.	metal oxide	25-36	strawberry notch homolog 1	Homo sapiens	68-71
18940810-1	2008	Binding of oleate to S-nitrosylated human serum albumin (SNO-HSA) enhances its cytoprotective effect on liver cells in a rat ischemia/reperfusion model.	Oleic Acid	11-17	strawberry notch homolog 1	Homo sapiens	57-60
18940810-6	2008	Likewise, binding of oleate, or of a mixture of endogenous fatty acids, improved S-denitrosation of SNO-HSA by HepG2 cells.	Fatty Acids	59-70	strawberry notch homolog 1	Homo sapiens	100-103
18940810-9	2008	Oleate also increased, in a dose-dependent manner, the binding of SNO-HSA labeled with fluorescein isothiocyanate to the surface of the hepatocytes.	Oleic Acid	0-6	strawberry notch homolog 1	Homo sapiens	66-69
18940810-9	2008	Oleate also increased, in a dose-dependent manner, the binding of SNO-HSA labeled with fluorescein isothiocyanate to the surface of the hepatocytes.	Fluorescein-5-isothiocyanate	87-113	strawberry notch homolog 1	Homo sapiens	66-69
18940810-11	2008	Fatty acid binding facilitates S-denitrosation of SNO-HSA, increases its binding to HepG2 cells and greatly increases S-transnitrosation by hepatocytes in a way that is sensitive to filipin III.	Fatty Acids	0-10	strawberry notch homolog 1	Homo sapiens	50-53
19094028-0	2008	Combined FTIR and SEM-EDS study of Bi2O3 doped ZnO-SnO2 ceramics.	bi2o3	35-40	strawberry notch homolog 1	Homo sapiens	51-54
19094028-1	2008	The effects of Bi(2)O(3) addition on the phase composition, microstructure and optical properties of ZnO-SnO(2) ceramics were investigated.	Zinc Oxide	101-104	strawberry notch homolog 1	Homo sapiens	105-108
19105789-1	2009	A facile and reproducible approach was reported to synthesize nanoparticle-attached SnO nanoflowers via decomposition of an intermediate product Sn6O4(OH)4.	sn6o4(oh)4	145-155	strawberry notch homolog 1	Homo sapiens	84-87
19105789-2	2009	Sn6O4(OH)4 formed after introducing water into the traditional nonaqueous reaction, and then decomposed to SnO nanoflowers with the help of free metal cations, such as Sn2+, Fe2+, and Mn2+.	sn6o4(oh)4	0-10	strawberry notch homolog 1	Homo sapiens	107-110
19105789-2	2009	Sn6O4(OH)4 formed after introducing water into the traditional nonaqueous reaction, and then decomposed to SnO nanoflowers with the help of free metal cations, such as Sn2+, Fe2+, and Mn2+.	Tin(2+)	168-172	strawberry notch homolog 1	Homo sapiens	107-110
19105789-2	2009	Sn6O4(OH)4 formed after introducing water into the traditional nonaqueous reaction, and then decomposed to SnO nanoflowers with the help of free metal cations, such as Sn2+, Fe2+, and Mn2+.	Manganese(2+)	184-188	strawberry notch homolog 1	Homo sapiens	107-110
19105789-4	2009	It was demonstrated further that the as-prepared SnO nanoflowers could be utilized as good anode materials for lithium ion rechargeable batteries with a high capacity of around 800 mA h g(-1), close to the theoretical value (875 mA h g(-1)).	Lithium	111-118	strawberry notch homolog 1	Homo sapiens	49-52
19123529-1	2008	Tin dioxide (SnO(2)) nanowires exhibit a strong visible photoluminescence that is not observed in bulk crystalline SnO(2).	stannic oxide	0-11	strawberry notch homolog 1	Homo sapiens	13-16
19123529-1	2008	Tin dioxide (SnO(2)) nanowires exhibit a strong visible photoluminescence that is not observed in bulk crystalline SnO(2).	stannic oxide	0-11	strawberry notch homolog 1	Homo sapiens	115-118
19123529-4	2008	On the basis of photoluminescence quenching analysis and of first-principles calculations we show that surface bridging oxygen vacancies in SnO(2) lead to formation of occupied and empty surface bands whose transition energies are in strong agreement with luminescence features and whose luminescence activity can be switched off by surface adsorption of oxidizing molecules.	Oxygen	120-126	strawberry notch homolog 1	Homo sapiens	140-143
21836306-0	2008	Synthesis, morphology and compositional evolution of silicon nanowires directly grown on SnO(2) substrates.	Silicon	53-60	strawberry notch homolog 1	Homo sapiens	89-92
21836306-1	2008	We here propose an all-in situ method for growing vapor-liquid-solid (VLS) silicon nanowires (SiNWs) directly on SnO(2) substrates in a plasma-enhanced chemical vapor deposition system.	Silicon	75-82	strawberry notch homolog 1	Homo sapiens	113-116
21836306-2	2008	The tin catalysts are formed by a well-controlled H(2) plasma treatment of the SnO(2) layer.	Tin	4-7	strawberry notch homolog 1	Homo sapiens	79-82
21836306-2	2008	The tin catalysts are formed by a well-controlled H(2) plasma treatment of the SnO(2) layer.	h(2)	50-54	strawberry notch homolog 1	Homo sapiens	79-82
18950221-5	2008	Moreover, the as-synthesized SnO(2) hollow spheres have been applied in lithium-ion battery and show improved performance compared with SnO(2) nanoparticles.	Lithium	72-79	strawberry notch homolog 1	Homo sapiens	29-32
18605706-1	2008	Crystalline SnO grown in a Sn 6O 4(OH) 4 matrix exhibited hierarchical architectures, such as stepped bipyramids, stacked meshes, and rosettes, which were not categorized into the classical assortment of crystal morphologies.	sn 6o 4(oh) 4	27-40	strawberry notch homolog 1	Homo sapiens	12-15
18710189-5	2008	O2 pressure was observed to decrease the SnO(x) film conductivity.	Oxygen	0-2	strawberry notch homolog 1	Homo sapiens	41-44
18710189-11	2008	These results indicate that CO can produce oxygen vacancies on the SnO(x) surface that ionize and release electrons that increase the SnO(x) film conductivity, as suggested by the oxygen-vacancy model.	Oxygen	43-49	strawberry notch homolog 1	Homo sapiens	67-70
18710189-11	2008	These results indicate that CO can produce oxygen vacancies on the SnO(x) surface that ionize and release electrons that increase the SnO(x) film conductivity, as suggested by the oxygen-vacancy model.	Oxygen	43-49	strawberry notch homolog 1	Homo sapiens	134-137
18710189-11	2008	These results indicate that CO can produce oxygen vacancies on the SnO(x) surface that ionize and release electrons that increase the SnO(x) film conductivity, as suggested by the oxygen-vacancy model.	Oxygen	180-186	strawberry notch homolog 1	Homo sapiens	67-70
18710189-11	2008	These results indicate that CO can produce oxygen vacancies on the SnO(x) surface that ionize and release electrons that increase the SnO(x) film conductivity, as suggested by the oxygen-vacancy model.	Oxygen	180-186	strawberry notch homolog 1	Homo sapiens	134-137
18710189-12	2008	The time scale of the response of the SnO(x) films to O2 and CO pressure was also measured by using transient experiments.	Oxygen	54-56	strawberry notch homolog 1	Homo sapiens	38-41
18710189-12	2008	The time scale of the response of the SnO(x) films to O2 and CO pressure was also measured by using transient experiments.	Carbon Monoxide	61-63	strawberry notch homolog 1	Homo sapiens	38-41
18710189-13	2008	The ultrathin SnO(x) ALD films with a thickness of approximately 10 A were able to respond to O2 within approximately 100 s and to CO within approximately 10 s. These in situ transmission FTIR spectroscopy help confirm the mechanisms for chemiresistant semiconductor gas sensors.	Oxygen	94-96	strawberry notch homolog 1	Homo sapiens	14-17
18680263-6	2008	SnO2/TiO2/SnO2 presents larger values of surface energy than the individual SnO2 and TiO2 metal oxides and the TiO2/SnO2/TiO2 system renders surface energy values of the same order that the TiO2 and lower than the SnO2.	titanium dioxide	5-9	strawberry notch homolog 1	Homo sapiens	0-3
18680263-6	2008	SnO2/TiO2/SnO2 presents larger values of surface energy than the individual SnO2 and TiO2 metal oxides and the TiO2/SnO2/TiO2 system renders surface energy values of the same order that the TiO2 and lower than the SnO2.	tio2 metal oxides	85-102	strawberry notch homolog 1	Homo sapiens	0-3
18680263-6	2008	SnO2/TiO2/SnO2 presents larger values of surface energy than the individual SnO2 and TiO2 metal oxides and the TiO2/SnO2/TiO2 system renders surface energy values of the same order that the TiO2 and lower than the SnO2.	titanium dioxide	85-89	strawberry notch homolog 1	Homo sapiens	0-3
18680263-6	2008	SnO2/TiO2/SnO2 presents larger values of surface energy than the individual SnO2 and TiO2 metal oxides and the TiO2/SnO2/TiO2 system renders surface energy values of the same order that the TiO2 and lower than the SnO2.	titanium dioxide	85-89	strawberry notch homolog 1	Homo sapiens	0-3
18680263-6	2008	SnO2/TiO2/SnO2 presents larger values of surface energy than the individual SnO2 and TiO2 metal oxides and the TiO2/SnO2/TiO2 system renders surface energy values of the same order that the TiO2 and lower than the SnO2.	titanium dioxide	85-89	strawberry notch homolog 1	Homo sapiens	0-3
18680263-7	2008	An analysis of the electronic structure of the TiO2/SnO2/TiO2 and SnO2/TiO2/SnO2 systems shows that the main characteristics of the upper part of the valence bands for all the studied surfaces are dominated by the external layers, i.e., by the TiO2 and the SnO2, respectively, and the topology of the lower part of the conduction bands looks like the core layers.	titanium dioxide	47-51	strawberry notch homolog 1	Homo sapiens	52-55
18712914-1	2008	Mono- and bilayer adsorption of H2O molecules on TiO2 and SnO 2 (110) surfaces has been investigated using static planewave density functional theory (PW DFT) simulations.	Water	32-35	strawberry notch homolog 1	Homo sapiens	58-61
18512700-1	2008	Nano- and microstructures of SnO(2), In(2)O(3) and ZnO have been grown during thermal treatment of compacted powders under argon flow.	Argon	123-128	strawberry notch homolog 1	Homo sapiens	29-32
18565568-1	2008	SO(2) reduction by CO over SnO(2) catalyst was studied in this work.	Carbon Monoxide	19-21	strawberry notch homolog 1	Homo sapiens	27-30
18565568-5	2008	The following reaction pathway involving two mechanisms was proposed in SO(2) reduction by CO over SnO(2) catalyst: in the first step involving Redox mechanism, the elemental sulfur was produced by the mobility of the lattice oxygen between SO(2) and SnO(2) surface.	Sulfur	175-181	strawberry notch homolog 1	Homo sapiens	99-102
18565568-5	2008	The following reaction pathway involving two mechanisms was proposed in SO(2) reduction by CO over SnO(2) catalyst: in the first step involving Redox mechanism, the elemental sulfur was produced by the mobility of the lattice oxygen between SO(2) and SnO(2) surface.	Sulfur	175-181	strawberry notch homolog 1	Homo sapiens	251-254
18565568-5	2008	The following reaction pathway involving two mechanisms was proposed in SO(2) reduction by CO over SnO(2) catalyst: in the first step involving Redox mechanism, the elemental sulfur was produced by the mobility of the lattice oxygen between SO(2) and SnO(2) surface.	Oxygen	226-232	strawberry notch homolog 1	Homo sapiens	99-102
18565568-5	2008	The following reaction pathway involving two mechanisms was proposed in SO(2) reduction by CO over SnO(2) catalyst: in the first step involving Redox mechanism, the elemental sulfur was produced by the mobility of the lattice oxygen between SO(2) and SnO(2) surface.	Oxygen	226-232	strawberry notch homolog 1	Homo sapiens	251-254
18516054-2	2008	One mechanism proposed to explain this oxygen-sensing-NO bioactivity linkage postulates an essential role for the conserved Cys93 residue of the hemoglobin beta-chain (betaCys93) and, specifically, for S-nitrosation of betaCys93 to form S-nitrosohemoglobin (SNO-Hb).	Oxygen	39-45	strawberry notch homolog 1	Homo sapiens	258-261
18512700-2	2008	Indium-doped SnO(2) tube-shaped structures with rectangular cross-section are obtained by adding a fraction of In(2)O(3) to the starting SnO(2) powder.	Indium	0-6	strawberry notch homolog 1	Homo sapiens	13-16
18512700-2	2008	Indium-doped SnO(2) tube-shaped structures with rectangular cross-section are obtained by adding a fraction of In(2)O(3) to the starting SnO(2) powder.	Indium	0-6	strawberry notch homolog 1	Homo sapiens	137-140
18512700-4	2008	ZnO nanostructures doped with Sn or Eu were grown by adding SnO(2) and Eu(2)O(3) powder, respectively, to the ZnO precursor powder.	Zinc Oxide	0-3	strawberry notch homolog 1	Homo sapiens	60-63
18512700-4	2008	ZnO nanostructures doped with Sn or Eu were grown by adding SnO(2) and Eu(2)O(3) powder, respectively, to the ZnO precursor powder.	Tin	30-32	strawberry notch homolog 1	Homo sapiens	60-63
21825811-1	2008	Thick film resistive Cl(2) sensors were fabricated using SnO(2) doped with Sb.	Chlorine	21-26	strawberry notch homolog 1	Homo sapiens	57-60
21828666-1	2008	A high-yield synthesis of SnO(2) nanoparticles via a facile, economical and easily scalable solid-state molten salt synthesis method has been demonstrated.	Salts	111-115	strawberry notch homolog 1	Homo sapiens	26-29
21828666-4	2008	Hydrogen sensors made from the SnO(2) nanoparticles were found to possess high sensitivity and stability.	Hydrogen	0-8	strawberry notch homolog 1	Homo sapiens	31-34
21825811-0	2008	Room temperature Cl(2) sensing using thick nanoporous films of Sb-doped SnO(2).	Chlorine	17-22	strawberry notch homolog 1	Homo sapiens	72-75
21825811-1	2008	Thick film resistive Cl(2) sensors were fabricated using SnO(2) doped with Sb.	Antimony	75-77	strawberry notch homolog 1	Homo sapiens	57-60
21825811-2	2008	The nanocrystalline powders of Sb-doped SnO(2) synthesized by a sol-gel method were compressed into an 800 microm thick pellet.	Antimony	31-33	strawberry notch homolog 1	Homo sapiens	40-43
21825811-6	2008	It was found that the SnO(2) doped with 0.1% Sb exhibited high response, selectivity (&gt;100 in comparison to the gases described above) and short response time (~60 s) to Cl(2) at 3 ppm level at room temperature.	Antimony	45-47	strawberry notch homolog 1	Homo sapiens	22-25
21825811-6	2008	It was found that the SnO(2) doped with 0.1% Sb exhibited high response, selectivity (&gt;100 in comparison to the gases described above) and short response time (~60 s) to Cl(2) at 3 ppm level at room temperature.	Chlorine	173-178	strawberry notch homolog 1	Homo sapiens	22-25
21825741-1	2008	SnO(2)/alpha-Fe(2)O(3) hierarchical nanostructures, in which the SnO(2) nanorods grow on the side surface of alpha-Fe(2)O(3) nanorods as multiple rows, were synthesized via a three-step process.	alpha-fe(2)o	109-121	strawberry notch homolog 1	Homo sapiens	0-3
21825741-3	2008	The growth direction of SnO(2) nanorods is [001], significantly affected by that of alpha-Fe(2)O(3) nanorods.	Iron	89-92	strawberry notch homolog 1	Homo sapiens	24-27
21825701-0	2008	The template-free synthesis of square-shaped SnO(2) nanowires: the temperature effect and acetone gas sensors.	Acetone	90-97	strawberry notch homolog 1	Homo sapiens	45-48
21825701-7	2008	Chemical sensors constructed with square-shaped SnO(2) nanowires exhibit excellent stability, good sensitivity and selectivity, as well as a quick response and short recovery times under exposure to acetone gas in practical applications.	Acetone	199-206	strawberry notch homolog 1	Homo sapiens	48-51
17222510-1	2007	The properties of the interlayer and outer layer of Ti/Co/SnO2-Sb2O5 electrode were studied, and the electrochemical behavior was examined as well.	sb2o5	63-68	strawberry notch homolog 1	Homo sapiens	58-61
21817675-4	2008	Our sensor showed higher sensitivity compared to different types of sensors including SnO(2) powder-based thin films, SnO(2) coating on carbon nanotubes or single/multiple SnO(2) nanobelts.	Carbon	136-142	strawberry notch homolog 1	Homo sapiens	118-121
21817675-4	2008	Our sensor showed higher sensitivity compared to different types of sensors including SnO(2) powder-based thin films, SnO(2) coating on carbon nanotubes or single/multiple SnO(2) nanobelts.	Carbon	136-142	strawberry notch homolog 1	Homo sapiens	118-121
21817690-1	2008	Well-crystalline SnO(2) nanorods have been synthesized successfully via a lithium-assisted solution-phase method.	Lithium	74-81	strawberry notch homolog 1	Homo sapiens	17-20
21817690-3	2008	The experimental results show that lithium addition plays a critical role in the formation of SnO(2) nanorods, and the correlation between the surface energy change and morphological evolution of this material is also discussed.	Lithium	35-42	strawberry notch homolog 1	Homo sapiens	94-97
17760477-2	2007	We found that the electronic conductivity of the individual SnO(2)-In(2)O(3) nanowires was 2 orders of magnitude better than that of the pure SnO(2) nanowires, due to the formation of Sn-doped In(2)O(3) caused by the incorporation of Sn into the In(2)O(3) lattice during the nucleation and growth of the In(2)O(3) shell nanostructures.	Tin	60-62	strawberry notch homolog 1	Homo sapiens	142-145
17760477-3	2007	This provides the SnO(2)-In(2)O(3) nanowires with an outstanding lithium storage capacity, making them suitable for promising Li ion battery electrodes.	Lithium	65-72	strawberry notch homolog 1	Homo sapiens	18-21
21817675-1	2008	We fabricated a nanowire-based gas sensor using a simple method of growing SnO(2) nanowires bridging the gap between two pre-patterned Au catalysts, in which the electrical contacts to the nanowires are self-assembled during the synthesis of the nanowires.	Gold	135-137	strawberry notch homolog 1	Homo sapiens	75-78
18479049-7	2008	XPS investigation shows that after annealing the oxygen content of the film increases, O1s peak shifts to lower energies, and SnO is oxidized into SnO2, After annealing the intrinsic SnO2 films of high-resistance as a buffer layer are very suitable for the CdTe solar cells.	Tin(IV) oxide	147-151	strawberry notch homolog 1	Homo sapiens	126-129
18479049-7	2008	XPS investigation shows that after annealing the oxygen content of the film increases, O1s peak shifts to lower energies, and SnO is oxidized into SnO2, After annealing the intrinsic SnO2 films of high-resistance as a buffer layer are very suitable for the CdTe solar cells.	Tin(IV) oxide	183-187	strawberry notch homolog 1	Homo sapiens	126-129
18479049-7	2008	XPS investigation shows that after annealing the oxygen content of the film increases, O1s peak shifts to lower energies, and SnO is oxidized into SnO2, After annealing the intrinsic SnO2 films of high-resistance as a buffer layer are very suitable for the CdTe solar cells.	cadmium telluride	257-261	strawberry notch homolog 1	Homo sapiens	126-129
17989798-0	2007	Oxygen-17 hyperfine structures in the pure rotational spectra of SrO, SnO, BaO, HfO and ThO.	Oxygen	0-6	strawberry notch homolog 1	Homo sapiens	70-73
17476405-1	2007	A unique nanocrystalline, mesoporous PdO-SnO(2) film exhibiting high sensitivity and selectivity to hydrogen gas at room temperature has been developed.	Hydrogen	100-108	strawberry notch homolog 1	Homo sapiens	41-44
17501589-0	2007	Growth of one-dimensional Pd nanowires on the terraces of a reduced SnO2(101) surface.	Palladium	26-28	strawberry notch homolog 1	Homo sapiens	68-71
17501589-1	2007	Palladium, vapor-deposited at room temperature on a reduced SnO2(101) surface, forms one-dimensional islands, one atomic layer high, 5 A wide, and up to 350 A long.	Palladium	0-9	strawberry notch homolog 1	Homo sapiens	60-63
17260951-8	2007	The three molecules are in general agreement but display subtle differences, including both cis and trans conformers for Cys 69 SNO in molecule C, and greater disorder in the Cys 62-Cys 69 helix in molecule B.	Cysteine	121-124	strawberry notch homolog 1	Homo sapiens	128-131
17676572-3	2007	The same approach was used to grow branched ZnO-SnO(2) heterojunction nanostructures.	Zinc Oxide	44-47	strawberry notch homolog 1	Homo sapiens	48-51
17013961-0	2007	Structures and vibrational spectra of the sulfur-rich oxides SnO (n = 4-9): the importance of pi*-pi* interactions.	sulfur-rich oxides	42-60	strawberry notch homolog 1	Homo sapiens	61-64
17041672-1	2006	ZnO/SnO nanocomposites have been designed to enhance the band edge emission and suppress the defect emission of ZnO nanorods simultaneously.	Zinc Oxide	0-3	strawberry notch homolog 1	Homo sapiens	4-7
17041672-1	2006	ZnO/SnO nanocomposites have been designed to enhance the band edge emission and suppress the defect emission of ZnO nanorods simultaneously.	Zinc Oxide	112-115	strawberry notch homolog 1	Homo sapiens	4-7
17041672-3	2006	The underlying mechanism is interpreted in terms of surface modification as well as carrier transfer from SnO nanoparticles to ZnO nanorods.	Zinc Oxide	127-130	strawberry notch homolog 1	Homo sapiens	106-109