PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
33807340-2	2021	Information on the photoelectric and optical properties of nanocrystalline oxides SnO2, ZnO, In2O3, and WO3, which are the most widely used sensitive materials for semiconductor gas sensors, is presented.	Tin(IV) oxide	82-86	gastrin	Homo sapiens	178-181	
32962335-0	2020	Double-Step Modulation of Pulse-Driven Mode for High Performance SnO2 Micro Gas Sensor: Designing the Particle Surface via Rapid Preheating Process.	Tin(IV) oxide	65-69	gastrin	Homo sapiens	76-79	
32962335-4	2020	Temperature programmed reaction (TPR) measurement results show that ethanol gas was adsorbed onto the SnO2 surface at 30  C, and the adsorption amount of ethanol and its byproducts was increased after ethanol exposure at high temperatures followed by cooling.	Tin(IV) oxide	102-106	gastrin	Homo sapiens	76-79	
32854509-2	2020	In this work, a two-site Langmuir kinetics model is applied to describe the adsorption/desorption response processes of a SnO2/reduced graphene oxide resistive gas sensor and the pertinent kinetic parameters are optimized based on the genetic algorithm (GA).	Tin(IV) oxide	122-126	gastrin	Homo sapiens	160-163	
32604577-1	2020	SnO2 thin-film gas sensors were easily created using the ion sputtering technique.	Tin(IV) oxide	0-4	gastrin	Homo sapiens	15-18	
32604577-5	2020	The responses of the SnO2 thin-film sensors decrease as the SnO2 film thickness is increased, indicating that a negative association exists between the sensor response and the SnO2 film thickness due to gas diffusion from the surface.	Tin(IV) oxide	21-25	gastrin	Homo sapiens	203-206	
32604577-5	2020	The responses of the SnO2 thin-film sensors decrease as the SnO2 film thickness is increased, indicating that a negative association exists between the sensor response and the SnO2 film thickness due to gas diffusion from the surface.	Tin(IV) oxide	60-64	gastrin	Homo sapiens	203-206	
32604577-5	2020	The responses of the SnO2 thin-film sensors decrease as the SnO2 film thickness is increased, indicating that a negative association exists between the sensor response and the SnO2 film thickness due to gas diffusion from the surface.	Tin(IV) oxide	60-64	gastrin	Homo sapiens	203-206	
32604577-6	2020	The SnO2 thin-film sensor, which was created by ion sputtering for 10 min, shows an excellent sensor response (Ra/Rg where Ra is the electric resistance under air and Rg is the electric resistance under the test gas) for detecting 1 ppm H2S at 350 C.	Tin(IV) oxide	4-8	gastrin	Homo sapiens	212-215	
33540619-3	2021	Here, SnO2/graphene nanocomposite is taken as a typical example and develops a universal synthesis method that overcome these challenges and prepares the oxygen-deficient SnO2 hollow nanospheres/graphene (r-SnO2/GN) nanocomposite with excellent performance for supercapacitors and gas sensors.	Tin(IV) oxide	6-10	gastrin	Homo sapiens	281-284	
34914352-2	2022	Our SnO2 nanosheet gas sensor can detect 50 ppb of acetone without the requirement of a novel metal catalyst by exposing the (101) facet containing the Sn2+ state.	Tin(IV) oxide	4-8	gastrin	Homo sapiens	19-22	
34914352-9	2022	To prepare a database for an effective predictive model, the gas responses of the SnO2 nanosheet sensor were measured with 20 treatments with 3 independent variables, namely, the temperature, flow rate, and concentration.	Tin(IV) oxide	82-86	gastrin	Homo sapiens	61-64	
34109783-0	2021	Optimized Electrode/Electrolyte Interface of MWCNT/SnO2 Composite through Gas-Solid Fluorination.	Tin(IV) oxide	51-55	gastrin	Homo sapiens	74-77