Journal
JOURNAL OF HAZARDOUS MATERIALS
Volume 443, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.jhazmat.2022.130316
Keywords
WO3; WS2 composite; Hydrothermal; NO2; Gas sensing
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Efficient detection of ultra-low concentrations of hazardous gases, such as NO2, can be achieved using nanoflower-like WO3/WS2 composites. These composites exhibit high sensitivity, selectivity, reproducibility, and long-term stability, making them suitable for air pollution monitoring and ecosystem and human health protection.
Realizing efficient detection of ultra-low concentrations of hazardous gases contributes to air pollution monitoring, ecosystem and human health protection. Herein, we firstly fabricated the nanoflower-like WO3/WS2 composites by a facile process to highly sensitively detect NO2 at room temperature. The WO3 content in the WO3/WS2 composites can be adjusted by altering the calcination temperature, and the WO3 nanoparticles disperse uniformly on the WS2 surface, forming the WO3/WS2 heterojunction. The room-temperature responses of WO3/WS2 composites gradually climb with the NO2 concentration increasing from 0.005 to 5 ppm, and the WW-280 and WW-300 composites possess the optimal gas sensitivity when the NO2 concentrations are lower and higher than 100 ppb, respectively. In particular, the two WO3/WS2 composites present the limitation of detection (LOD) of <= 5 ppb, and they exhibit the excellent selectivity, good reproducibility and long-term stability towards NO2. A possible gas sensing mechanism was also proposed from the point of views of gas adsorption, redox reactions and electron transfer. The appropriate WO3 content and molar ratio of hexagonal to monoclinic WO3, and the formation of WO3/WS2 p-n heterojunction can contribute to the high sensitivity of WO3/WS2 composite
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