Defect engineering on SnO2 nanomaterials for enhanced gas sensing performances

• Published in: Advanced Powder Materials Vol. 1; no. 3; p. 100033
• Main Authors: Xiong, Ya, Lin, Yueqiang, Wang, Xinzhen, Zhao, Yi, Tian, Jian
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.07.2022; KeAi Communications Co. Ltd
• Subjects: Defect design principles; Defect engineering; Defect types; Gas sensor; SnO2 nanostructure; Defect types; Defect engineering; Gas sensor; SnO2 nanostructure; Defect design principles
• ISSN: 2772-834X; 2772-834X
• DOI: 10.1016/j.apmate.2022.02.001

Although defect engineering opens up new opportunities in the field of gas sensors, the introduction of defects to enhance the gas sensing properties of metal oxide semiconductors (MOSs) has long been neglected. In this review, defect engineering strategies have been systematically introduced, with a focus on employing them for improved gas sensing performances. To keep the subject focused, we take SnO2 nanomaterials as an example. Various synthesis methods for defective SnO2, including ion/electron/ray/laser-beam irradiation, plasma treatment, heating protocol, chemical reduction, tailoring specially exposed crystal facets and atoms doping, are emphasized. Different roles of defects on the gas sensing process of SnO2 are discussed. Finally, critical issues and future directions of defect engineering are presented. This paper provides a platform for better understanding the relationships between synthesis, defect types and gas sensing performances of MOSs. It is also expected to unpack an important research direction for controlled synthesis of defective nanomaterials with other applications, including advanced energy conversion and storage. Defect engineering strategies have been utilized to optimize the gas sensing properties of SnO2 nanomaterials. [Display omitted] •The significant roles of defects in enhancing the gas sensing behavior of SnO2 are proposed.•Typical approaches for defects implantation on SnO2 are comprehensively investigated.•The underlying mechanisms of improved gas sensing performance based on SnO2 via defect engineering are discussed in detail.