To achieve the rapid and real-time detection of triethylamine(TEA)gas,this study synthesized a gas sensor based on heterostructures of Fe_(2)O_(3)/MoO_(3) using a hydrothermal method.Fe_(2)O_(3)/MoO_(3) composites wit...To achieve the rapid and real-time detection of triethylamine(TEA)gas,this study synthesized a gas sensor based on heterostructures of Fe_(2)O_(3)/MoO_(3) using a hydrothermal method.Fe_(2)O_(3)/MoO_(3) composites with a narrow bandgap(1.1 eV)were successfully synthesized by constructing heterostructures.The rapid and efficient detection of triethylamine was achieved at 220℃.The response and response/recovery times of the Fe_(2)O_(3)/MoO_(3) sensor with 50×10^(−6) triethylamine were 132 s and 5 s/10 s,respectively.The Fe_(2)O_(3)/MoO_(3) sensor maintained a good response to triethylamine gas,even at 80%relative humidity.The sensing mechanism of the Fe_(2)O_(3)/MoO_(3) sensor can be described in terms of adsorption energy and electronic behavior of the sensing layer using density functional theory(DFT).The results are consistent with the excellent selectivity and rapid response/recovery of the Fe_(2)O_(3)/MoO_(3) gas sensor for triethylamine.Therefore,the construction of heterostructures to facilitate electron transmission is an effective strategy to achieve rapid detection of triethylamine and is worthy of further exploration and investigation.展开更多
基金supported by National Natural Science Foundation of China(Nos.61102006 and 51803109)Natural Science Foundation of Shandong Province,China(ZR2022MF234 and No.ZR2018LE006).
文摘To achieve the rapid and real-time detection of triethylamine(TEA)gas,this study synthesized a gas sensor based on heterostructures of Fe_(2)O_(3)/MoO_(3) using a hydrothermal method.Fe_(2)O_(3)/MoO_(3) composites with a narrow bandgap(1.1 eV)were successfully synthesized by constructing heterostructures.The rapid and efficient detection of triethylamine was achieved at 220℃.The response and response/recovery times of the Fe_(2)O_(3)/MoO_(3) sensor with 50×10^(−6) triethylamine were 132 s and 5 s/10 s,respectively.The Fe_(2)O_(3)/MoO_(3) sensor maintained a good response to triethylamine gas,even at 80%relative humidity.The sensing mechanism of the Fe_(2)O_(3)/MoO_(3) sensor can be described in terms of adsorption energy and electronic behavior of the sensing layer using density functional theory(DFT).The results are consistent with the excellent selectivity and rapid response/recovery of the Fe_(2)O_(3)/MoO_(3) gas sensor for triethylamine.Therefore,the construction of heterostructures to facilitate electron transmission is an effective strategy to achieve rapid detection of triethylamine and is worthy of further exploration and investigation.
