Litcius/Paper detail

Heterojunctions of ZnO-Nanorod-Decorated WO<sub>3</sub> Nanosheets Coated with ZIF-71 for Humidity-Independent NO<sub>2</sub> Sensing

L.Q. Qian, Canxiang Fang, Yanghai Gui, Kuan Tian, Huishi Guo, Dongjie Guo, Xiang Guo, Peng Liu

2023ACS Applied Nano Materials18 citationsDOI

Abstract

NO 2 is a very dangerous and toxic gas and is prone to cause acid rain in high humidity environments, so it is essential to prepare a real-time monitoring and humidity immunity NO 2 sensor. WO 3 nanomaterials are commonly applied to detect NO 2, but their poor immunity to humidity is still a critical limitation for the application. ZnO-nanorod-decorated WO 3 nanosheets coated with ZIF-71 (ZnO@ZIF-71/WO 3 ) composites prepared by an in situ growth method displayed excellent gas sensing performance and good humidity immunity to detect NO 2 . Compared to WO 3 nanosheets and ZnO-nanorod-decorated WO 3 nanosheets (ZnO/WO 3 ) heterojunction composites grown on ceramic substrates in situ, ZnO@ZIF-71/WO 3 presented excellent selectivity, good long-term stability, and a remarkably high response of about 947.96 to 100 ppm NO 2 at 180 °C, which is 3.07 times higher than that of the ZnO/WO 3 sensor and 4.59 times higher than that of the pure WO 3 sensor. Even at a relative humidity of 85%, the response of ZnO@ZIF-71/WO 3 to NO 2 remained essentially constant. The functional ZIF-71 layer not only improved the humidity immunity of ZnO@ZIF-71/WO 3 but also enhanced the sensitivity and selectivity performance to NO 2 at low operating temperatures. The ZnO@ZIF-71/WO 3 sensor still provided a response of 88.41 to 100 ppm NO 2 at room temperature.

Topics & Concepts

NanorodHumidityHeterojunctionMaterials scienceRelative humiditySelectivityNanotechnologyChemical engineeringNanomaterialsOptoelectronicsChemistryCatalysisBiochemistryThermodynamicsEngineeringPhysicsGas Sensing Nanomaterials and SensorsAnalytical Chemistry and SensorsAdvanced Chemical Sensor Technologies