氢
材料科学
氧化物
兴奋剂
氧气
吸附
解吸
金属
化学工程
纳米技术
氢传感器
催化作用
制氢
无机化学
间质缺损
化学物理
动力学
碱金属
半导体
电子转移
作者
Hejie Wang,Hao-Nan Chen,Xuan-Yu Yang,Fei-Long Gong,Kefeng Xie,Shi-Zhong Wei,Yong-Hui Zhang
出处
期刊:ACS Sensors
[American Chemical Society]
日期:2026-02-16
卷期号:11 (3): 2282-2294
标识
DOI:10.1021/acssensors.5c04097
摘要
The development of highly sensitive and reliable hydrogen detection technology is a critical prerequisite for the safe and large-scale application of green hydrogen energy. Pd-based metal oxide semiconductor sensors exhibit decent sensing performance; however, their development for hydrogen detection is hindered by competitive adsorption of hydrogen and oxygen on the surface and sluggish reaction kinetics due to limited active interfaces. Here, a series of Pd nanoparticle-decorated, K + interstitial doping WO 3 nanosheets (Pd NP -K/WO 3 - x ) were synthesized. The optimized Pd NP -K/WO 3 -15 sample exhibited exceptional H 2 sensing performance, including a high response ( R a / R g = 1235.94 to 50 ppm H 2 ) at a low temperature of 130 °C, with fast response/recovery. This enhancement stems from synergistic effects where K + interstitial doping increases electron density and oxygen vacancies in WO 3, improving charge transfer and strengthening the W-O-Pd interface. The resulting electron-rich environment also shifts the d -band center of Pd, enhancing hydrogen desorption and spillover, while reducing competitive oxygen adsorption to free up more Pd active sites. The material also showed promising room-temperature sensing, indicating strong application potential and providing a theoretical basis for designing high-performance alkali metal ion-doped metal oxide materials.
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