PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
30848880-7	2019	Furthermore, because the Fermi level of the SnO2{221} facet is higher than that of graphene, the electrons are transferred from SnO2 nanoparticles to graphene sheets, enabling effective electron exchange between the composite and external NO2 gas.	Graphite	150-158	strawberry notch homolog 2	Homo sapiens	44-47	
31166936-5	2019	In particular, the optimized SnS2-SnO2/graphene photocatalyst can degrade 97.1% of RhB within 60 min, which is about 1.38 times greater than that of SnS2-SnO2 heterostructures.	Graphite	39-47	strawberry notch homolog 2	Homo sapiens	34-37	
30014061-4	2018	Moreover, the graphene nanosheet provides a large specific surface area for SnO2 nanoparticles to anchor on, which could efficiently overcome the structure destruction of SnO2-based electrodes during continuous charging and discharging tests.	Graphite	14-22	strawberry notch homolog 2	Homo sapiens	76-79	
30525394-5	2019	The power conversion efficiency (PCE) of PSCs based on the graphene-SnO2 ETL reached over 18% with negligible hysteresis.	Graphite	59-67	strawberry notch homolog 2	Homo sapiens	68-71	
28296060-3	2017	Herein, a novel monolithic optoelectronic device fabricated by a mask-free laser direct writing method is demonstrated in which in situ laser induced graphene-like materials are employed as lateral electrodes for flexible ZnS/SnO2 ultraviolet photodetectors.	Graphite	150-158	strawberry notch homolog 2	Homo sapiens	226-229	
29688654-2	2017	The effects of the vacuum annealing and ultraviolet (UV) ozone (O3) exposure of the bare graphene films prior to the thermal evaporation on the SnO(x) -Sn films" sensitivities, bonding states, and surface morphologies were investigated.	Graphite	89-97	strawberry notch homolog 2	Homo sapiens	144-147	
29688654-3	2017	With increasing annealing time, the coverage of the SnO(x) -Sn nanoparticles on the graphene increased and the p to n sensitivity transition occurred when n-type SnO(x) -Sn nanoparticles became dominant instead of the p-type graphene films for sensors without O3 exposure.	Graphite	84-92	strawberry notch homolog 2	Homo sapiens	52-55	
29688654-5	2017	The chemisorbed Sn on the graphene generated by O3 exposure was oxidized by highly reactive NO2, resulting in a p-type doping effect, which would lead to n- to p-type sensitivity transition when the hole concentration exceeded the initial electron concentration of the n-type SnO(x) -Sn compound films.	Graphite	26-34	strawberry notch homolog 2	Homo sapiens	276-279	
24299146-0	2014	Photogenerated carriers transfer in dye-graphene-SnO2 composites for highly efficient visible-light photocatalysis.	Graphite	40-48	strawberry notch homolog 2	Homo sapiens	49-52	
25483827-1	2015	Three-dimensional (3D) TiO2-SnO2-graphene aerogels (TTGs) were built up from the graphene oxide nanosheets supported with both TiO2 and SnO2 nanoparticles (NPs) via a facile hydrothermal assembly process.	Graphite	33-41	strawberry notch homolog 2	Homo sapiens	28-31	
25367289-1	2014	The catalytic role of germanium (Ge) was investigated to improve the electrochemical performance of tin dioxide grown on graphene (SnO(2)/G) nanocomposites as an anode material of lithium ion batteries (LIBs).	Graphite	121-129	strawberry notch homolog 2	Homo sapiens	131-134	
25179102-0	2014	Enhancing electrocatalytic performance of Sb-doped SnO 2 electrode by compositing nitrogen-doped graphene nanosheets.	Graphite	97-105	strawberry notch homolog 2	Homo sapiens	51-54	
27192399-6	2016	Moreover, the MoS2/SnO2 hybrid nanocomposite film sensor exhibited great enhancement in humidity sensing performances as compared to the pure MoS2, SnO2, and graphene counterparts.	Graphite	158-166	strawberry notch homolog 2	Homo sapiens	19-22	
25483827-0	2015	Hierarchical TiO2-SnO2-graphene aerogels for enhanced lithium storage.	Graphite	23-31	strawberry notch homolog 2	Homo sapiens	18-21	
25367289-2	2014	Germanium dioxide (GeO(20) and SnO(2) nanoparticles (<10 nm) were uniformly anchored on the graphene sheets via a simple single-step hydrothermal method.	Graphite	95-103	strawberry notch homolog 2	Homo sapiens	31-34	
24316886-3	2014	SnO and SnO2 nanoparticles are uniformly distributed on the surface of the graphene.	Graphite	75-83	strawberry notch homolog 2	Homo sapiens	0-3	
24316886-4	2014	Taking advantage of the high electron conductivity of graphene and the large theoretical capacity of SnO, this SnO/SnO2/GNS composite exhibits high charge/discharge capacity, good cycling stability and good rate capability.	Graphite	54-62	strawberry notch homolog 2	Homo sapiens	111-114	
24299146-2	2014	Here we report graphene-SnO2 aerosol nanocomposites that exhibit more superior dye adsorption capacity and photocatalytic efficiency compared with pure SnO2 quantum dots, P25 TiO2, and pure graphene aerosol under the visible light.	Graphite	15-23	strawberry notch homolog 2	Homo sapiens	24-27	
21967167-1	2011	In this study, the SnO(2) nanostructures and graphene-SnO(2) (G-SnO(2)) composite nanostructures were prepared on n-Si (100) substrates by electrophoretic deposition and magnetron sputtering techniques.	Graphite	45-53	strawberry notch homolog 2	Homo sapiens	54-57	
22894878-1	2012	Graphene sheets decorated with SnO(2) nanoparticles (RGO-SnO(2)) were prepared via a redox reaction between graphene oxide (GO) and SnCl(2).	Graphite	0-8	strawberry notch homolog 2	Homo sapiens	31-34	
22894878-1	2012	Graphene sheets decorated with SnO(2) nanoparticles (RGO-SnO(2)) were prepared via a redox reaction between graphene oxide (GO) and SnCl(2).	Graphite	0-8	strawberry notch homolog 2	Homo sapiens	57-60	
21967167-1	2011	In this study, the SnO(2) nanostructures and graphene-SnO(2) (G-SnO(2)) composite nanostructures were prepared on n-Si (100) substrates by electrophoretic deposition and magnetron sputtering techniques.	Graphite	45-53	strawberry notch homolog 2	Homo sapiens	54-57	
21967167-2	2011	The field emission of SnO(2) nanostructures is improved largely by depositing graphene buffer layer, and the field emission of G-SnO(2) composite nanostructures can also further be improved by decreasing sputtering time of Sn nanoparticles to 5 min.	Graphite	78-86	strawberry notch homolog 2	Homo sapiens	22-25	
21967167-5	2011	Our results indicated that graphene can also be used as buffer layer acting as interface modification to simultaneity improve the field emission and PL properties of SnO(2) nanostructures effectively.	Graphite	27-35	strawberry notch homolog 2	Homo sapiens	166-169	
21344871-0	2011	SnO(2) nanorod-planted graphite: an effective nanostructure configuration for reversible lithium ion storage.	Graphite	23-31	strawberry notch homolog 2	Homo sapiens	0-3	
21607244-1	2011	We demonstrate a new hydrothermal method to directly grow SnO(2) nanosheets on a graphene oxide support that is subsequently reduced to graphene.	Graphite	81-89	strawberry notch homolog 2	Homo sapiens	58-61	
21607244-2	2011	This unique SnO(2)/graphene hybrid structure exhibits enhanced lithium storage properties with high reversible capacities and good cycling performance.	Graphite	19-27	strawberry notch homolog 2	Homo sapiens	12-15	
21344871-1	2011	We report a novel architecture of SnO(2) nanorod-planted graphite particles for an efficient Li ion storage material that can be prepared by a simple catalyst-assisted hydrothermal process.	Graphite	57-65	strawberry notch homolog 2	Homo sapiens	34-37	
21344871-2	2011	Rectangular-shaped SnO(2) nanorods are highly crystalline with a tetragonal rutile phase and distributed uniformly over the surface of micrometer-sized graphite particles.	Graphite	152-160	strawberry notch homolog 2	Homo sapiens	19-22	
21344871-5	2011	Significantly, the SnO(2) nanorod-planted graphite demonstrates an initial Li ion storage capacity of about 1010 mAh g(-1) during the first cycle.	Graphite	42-50	strawberry notch homolog 2	Homo sapiens	19-22	
21344871-6	2011	Also, these SnO(2)-graphite composites show high Coulombic efficiency and cycle stability in comparison with SnO(2) nanomaterials that are not combined with graphite.	Graphite	19-27	strawberry notch homolog 2	Homo sapiens	12-15	
21344871-6	2011	Also, these SnO(2)-graphite composites show high Coulombic efficiency and cycle stability in comparison with SnO(2) nanomaterials that are not combined with graphite.	Graphite	19-27	strawberry notch homolog 2	Homo sapiens	109-112	
21344871-7	2011	The enhanced electrochemical properties of SnO(2) nanorod-planted graphite, as compared with bare SnO(2) materials, inspire better design of composite materials with effective nanostructural configurations for advanced electrodes in lithium ion batteries.	Graphite	66-74	strawberry notch homolog 2	Homo sapiens	43-46	
19420508-3	2009	SnO(2) nanowires are obtained when SnO(2) mixed with graphite is used as the source material; adding TiO(2) into the source reliably leads to the formation of nanobelts.	Graphite	53-61	strawberry notch homolog 2	Homo sapiens	0-3