PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
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	
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	
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	
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	
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	
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	
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	
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	
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	
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	
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	
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	
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	
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	
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	
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