Constructing Sn0.92In0.08O2–In2O3 heterostructure via the dual synergy for improving CO sensitivity

Constructing Sn0.92In0.08O2–In2O3 heterostructure via the dual synergy for improving CO sensitivity

Improving the CO sensitivity for SnO2-based gas sensors has always been worthy of attention. Herein, we put forward a novel thought to enhance CO sensing performance via taking advantages of the large specific surface area of Sn0.92In0.08O2 (SI0.08O, x = 0.08) by doping modification and the heteroju...

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Bibliographic Details
Published in:Materials science in semiconductor processing 2023-03, Vol.156, p.107292, Article 107292
Main Authors: Meng, Fan-Jian, Guo, Xing-Min
Format: Article
Language:eng
Subjects:
Abundant heterojunctions
CO sensitivity
In2O3 content
In3+ doping modification
Quantitative regulation
SI0.08O–In2O3 heterostructure construction
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Summary:Improving the CO sensitivity for SnO2-based gas sensors has always been worthy of attention. Herein, we put forward a novel thought to enhance CO sensing performance via taking advantages of the large specific surface area of Sn0.92In0.08O2 (SI0.08O, x = 0.08) by doping modification and the heterojunction effect by combining SI0.08O with In2O3 to construct n-n heterostructure. For better distinguishing the respective contributions of In3+ doping and heterostructure construction on improving sensing performance of pristine SnO2 towards CO, SIxO (x = 0.01, 0.03, 0.05, 0.08 and 0.10) were firstly tested to determine the optimum In3+ doping concentration, then SI0.08O–In2O3 nanocomposites (SI0.08O-xINO, x = 20, 30, 40 and 50, which indicates respectively the mole percentage of In3+ in Sn4+ and In3+) were successfully prepared by grinding-annealing methods and the effect of In2O3 content on CO sensitivity was investigated. Among these materials, a superior gas sensitivity of SI0.08O–40INO was realized with the response value of 15.2 towards 3000 ppm CO, which was over 1.5 times that of SI0.08O, and the response time was 18s. Besides, by tuning the In2O3 content in SI0.08O-xINO, the selectivity towards CO could increase up to 5 times that of pristine SnO2. The improved gas sensing performance of SI0.08O–40INO was mainly ascribed to the large specific surface area, the successful construction of electronic transmission channel, the formation of abundant number of SI0.08O–In2O3 heterojunctions and the high grain boundary barrier at the interface between SI0.08O and In2O3. This work also realized the quantitative regulation of the ratio relationship between the In3+-doped SnO2 and In2O3 in binary heterostructured nanocomposites. [Display omitted] •The proportional relationship between Sn1-xInxO2 and In2O3 in Sn1-xInxO2-In2O3 nanocomposite was regulated exactly.•The Sn0.92In0.08O2–In2O3 heterostructure was constructed via facile sol-gel and grinding-annealing methods.•The synergy effect between hetero-valent ions doping and n-n heterojunction construction contributed to efficient CO sensing.•The influence of In2O3 content in the Sn0.92In0.08O2–In2O3 nanocomposite on CO gas sensing performance was studied in detail.•The heterojunction effect and higher potential barrier accounted for the enhanced gas sensing performance.
ISSN:1369-8001
1873-4081