PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
28702988-1	2017	We report the facile synthesis of thin-walled SnO2 nanotubes (NTs) with numerous clustered pores (pore radius 6.56 nm) and high surface area (125.63 m2/g) via selective etching of core (SiO2) region in SiO2-SnO2 composite nanofibers (NFs), in which SnO2 phase preferentially occupies the shell while SiO2 is concentrated in the center of the composite NFs.	Tin(IV) oxide	207-211	strawberry notch homolog 2	Homo sapiens	46-49	
30199618-7	2018	SnO x films formed using ozone and water as a reactant showed an optical band gap of 3.60-3.17 eV and 2.24-2.30 eV and refractive indices of ~2.0 and ~2.6, respectively, which correspond to values typical of SnO2 and SnO.	Tin(IV) oxide	208-212	strawberry notch homolog 2	Homo sapiens	0-3	
30199618-8	2018	The bilayer structure of SnO/SnO2 was successfully fabricated on indium tin oxide (ITO) glass with nickel as a top electrode at 100  C. The SnO/SnO2 bilayer exhibited diode characteristics with a current rectification ratio of 15.	Tin(IV) oxide	144-148	strawberry notch homolog 2	Homo sapiens	25-28	
30199618-8	2018	The bilayer structure of SnO/SnO2 was successfully fabricated on indium tin oxide (ITO) glass with nickel as a top electrode at 100  C. The SnO/SnO2 bilayer exhibited diode characteristics with a current rectification ratio of 15.	Tin(IV) oxide	144-148	strawberry notch homolog 2	Homo sapiens	29-32	
31177957-2	2019	However, the synthesis of SnO is rather challenging due to the instability of the oxide, which is usually obtained as a by-product of SnO2 fabrication.	Tin(IV) oxide	134-138	strawberry notch homolog 2	Homo sapiens	26-29	
26890414-6	2016	The sensing material (Au-SnO2 nanocomposite) was synthesised starting from SnO nanoplates, then Au nanoparticles were attached chemically to the surface of SnO nanoplates, finally the mixture was heated at 700  C in an oven in air for 4 h. This composite material was sonicated for 2 h in terpineol to make a viscous homogeneous slurry and then "written" directly across the electrode area using the DPN technique without any mask.	Tin(IV) oxide	25-29	strawberry notch homolog 2	Homo sapiens	75-78	
27389518-5	2016	Consequently, the long-range ordering and lattice parameter of the SnO(001) single crystals started to change to make polycrystalline SnO2 at about 600  C. These results demonstrate the ability to tune the work function of the microplates and suggest an intriguing way to engineer the electrical properties of nanostructures.	Tin(IV) oxide	134-138	strawberry notch homolog 2	Homo sapiens	67-70	
26833714-4	2016	DFT calculations are used to show that nanoclusters of metal oxides such as TiO2 , SnO/SnO2 , PbO/PbO2 , ZnO and CuO are stable when adsorbed at rutile and anatase surfaces, and can lead to a significant red shift in the absorption edge which will induce visible light absorption; this is the first requirement for a useful photocatalyst.	Tin(IV) oxide	87-91	strawberry notch homolog 2	Homo sapiens	83-86	
25757694-8	2015	The SnO crystalline phase formation from this amorphous shell has been associated with the exothermic peaks on the first heating cycle of the nanoparticles, followed by a disproportionation reaction into metallic Sn and SnO2.The results also revealed that the surfactant and reducing agent cannot only affect the size and size distribution of the nanoparticles, they might also alter the ratio between the amorphous shell and the crystalline core in the structure of particles.	Tin(IV) oxide	220-224	strawberry notch homolog 2	Homo sapiens	4-7	
24936162-3	2014	For as deposited SnO2 nanolayers, a mixture of tin oxide (SnO) and tin dioxide (SnO2) with the [C]/[Sn] ratio of approximately 1.3 was observed.	Tin(IV) oxide	80-84	strawberry notch homolog 2	Homo sapiens	17-20	
24494636-8	2014	Taken together, these results indicate that Sn/SnOx nanoparticles have core/shell1/shell2 structure of Sn/SnO/SnO2 phases.	Tin(IV) oxide	110-114	strawberry notch homolog 2	Homo sapiens	47-50	
26808905-3	2016	We use DFT to show that nanoclusters of different metal oxides, TiO2, SnO/SnO2, PbO/PbO2, NiO and CuO can be adsorbed at rutile and anatase surfaces and can induce red shifts in the absorption edge to enable visible light absorption which is the first key requirement for a practical photocatalyst.	Tin(IV) oxide	74-78	strawberry notch homolog 2	Homo sapiens	70-73	
26528675-9	2015	X-ray photoelectron spectroscopy indicates surface oxidation of the SnO film to SnO2 in ambient atmosphere.	Tin(IV) oxide	80-84	strawberry notch homolog 2	Homo sapiens	68-71	
26123121-4	2015	Compared to the single SnO2-based material, a gas sensor fabricated from the SnO2-SnO composite exhibited an enhanced sensing performance for NO2 gas detection, with a limit of detection and sensitivity of 0.1 ppm and 0.26 ppm(-1), respectively, at a relatively low operating temperature (50  C).	Tin(IV) oxide	23-27	strawberry notch homolog 2	Homo sapiens	77-80	
24316886-0	2014	A facile one-pot reduction method for the preparation of a SnO/SnO2/GNS composite for high performance lithium ion batteries.	Tin(IV) oxide	63-67	strawberry notch homolog 2	Homo sapiens	59-62