材料科学
合金
氢
解耦(概率)
吸附
氢溢流
纳米技术
敏化
选择性
单层
溢出效应
催化作用
纳米颗粒
钯
化学工程
基质(水族馆)
氢传感器
光电子学
纳米复合材料
检出限
调制(音乐)
作者
Ou Wang,Leiyu Diao,Pengfei Li,Youyou Feng,Dong Cheng,Yaqiong Su,Jing Wei
摘要
ABSTRACT Pd‐based nanoparticles have been widely employed to enhance H 2 sensing performance due to their strong capability for H 2 adsorption and dissociation. However, strong Pd–H* interactions hinder the hydrogen spillover process, while pronounced CO adsorption results in poor selectivity. Herein, we propose a Pt–Pd single‐atom alloy (SAA) sensitization strategy that creates electron‐deficient Pd δ+ sites to modulate the interaction between Pd and gas molecules. As a proof of concept, Pt 1 Pd SAA is deposited on commercial SnO 2 to fabricate H 2 sensors. The resulting device achieves an ultra‐low detection limit (21 ppb), short response and recovery time (0.8 s and 5.9 s), excellent selectivity and enhanced CO resistance, outperforming traditional Pd nanoparticles, PtPd alloy sensitizers modified SnO 2 gas sensors, and commercial H 2 sensors. Mechanistic studies establish that atomic Pt induces electron‐deficient Pd δ+ sites, achieving atomic‐scale decoupling of hydrogen activation from CO adsorption, which enables barrierless hydrogen spillover and inherently CO‐resistance H 2 sensing, with CO back‐donation suppressed by nearly 50%. This study presents a robust SAA sensitization strategy that leverages atomic‐level modification‐induced electronic structure modulation to overcome the sensitivity‐selectivity trade‐off, demonstrating its promise for next‐generation H 2 sensors.
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