Synergistic effects of SnO2 and Au nanoparticles decorated on WS2 nanosheets for flexible, room-temperature CO gas sensing

In this study, WS2 nanosheets that are bare or decorated with Au, SnO2, or a combination of Au and SnO2 were realized on flexible polyamide substrates. The fabricated sensors were operated for CO gas sensing in applied-voltage-induced self-heating mode. Not only optimal applied voltage was varied for the sensing of different gases, but also that the sensors behaved uniquely in response to CO gas. In particular, the Au-SnO2-co-decorated WS2 nanosheet gas sensor under an optimized applied voltage of 4.7, displayed the highest response (R-a/R-g = 3.687-50 ppm CO gas) and the highest selectivity to CO gas among the different gas sensors investigated. Furthermore, the optimized gas sensor indicated good gas response under tilting, bending and stretching conditions. The formation of Au-WS2 Schottky junctions, SnO2-WS2 heterojunctions and the role played by Au NPs in the catalysis CO gas were the most contributed effects to the sensing. The results obtained in this study provide new avenues towards fabrication of flexible, low power gas sensors using metal chalcogenides.

Automated summary

In this study, researchers fabricated WS2 nanosheets decorated with different materials on flexible substrates for CO gas sensing. The sensors exhibited unique responses and high selectivity to CO gas, with the Au-SnO2-co-decorated WS2 nanosheet sensor showing the highest response and selectivity. The presence of Au-WS2 Schottky junctions, SnO2-WS2 heterojunctions, and the catalytic role of Au nanoparticles in sensing CO gas were key factors contributing to the sensor's performance.