Cesium tungsten bronze nanostructures and their highly enhanced hydrogen gas sensing properties at room temperature

In this study, cesium tungsten bronze (CsxWO3) a well-known metal oxide semiconductor and excellentphotocatalystandactivephotothermal material was used as a sensing material toward hydrogen for the first time. The CsxWO3 nanorods were synthesized using a new hydrothermal method and examined through systematic material investigations. The synthesized CsxWO3 nanorods were coated on SiO2/Si substrates and subsequently fabricated laterally with multi finger platinum (Pt)-based electrodes to test their gas detecting properties. The gas detecting property of the prepared material was studied toward very toxic hydrogen gas (10-500 ppm concentration). The gas sensing results demonstrate that the synthesized CsxWO3 material has excellent gas sensing properties toward hydrogen (31.3%), which is overwhelmingly superior to as-prepared WO3 (4.7%) due to its suitable electrical and optical properties at room temperature (RT). The selectivity results also indicate that the material has outstanding selectivity toward hydrogen compared with different gases such as ammonia and carbon dioxide. The critical features of this material are its high reliability, simple synthesis method, low humidity susceptibility, and high selectivity, making it viable for use in hydrogen sensors. Compared with the as-prepared WO3, the adsorption capability and conductance of the CsxWO3 surface induces active O2 functional groups, significantly enhancing the gas sensing properties. (c) 2021 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved. Superscript/Subscript Available

Automated summary

In this study, cesium tungsten bronze (CsxWO3) was utilized for the first time as a sensing material towards hydrogen, demonstrating excellent gas sensing properties with high reliability, simple synthesis method, low humidity susceptibility, and high selectivity. The material’s adsorption capability and conductance on the surface induce active O2 functional groups, significantly enhancing the gas sensing properties, making it viable for use in hydrogen sensors.