金属间化合物
催化作用
材料科学
选择性
双功能
氧化物
纳米颗粒
吸附
化学工程
无机化学
原位
双功能催化剂
氧烷
协同催化
氧化还原
石墨烯
多相催化
选择性催化还原
X射线吸收光谱法
X射线吸收精细结构
扩展X射线吸收精细结构
串联
过渡金属
光谱学
工作(物理)
钯
作者
Jie Li,William Orbell,Fei Li,Yifan Li,Yunpeng Long,Yarong Bai,Lin Chen,Chuan Gao,L. N. Zhang,Junhua Li,Yue Peng
标识
DOI:10.1002/adfm.202530020
摘要
ABSTRACT Selective catalytic oxidation of NH3 is limited by a fundamental activity‐selectivity trade‐off: catalysts that accelerate low‐temperature turnover often promote NH 3 over‐oxidation to NO x and N 2 O at higher temperature. Here, we address this limitation with a bifunctional platinum‐copper catalyst that combines distinct intermetallic and oxide sites supported on γ‐Al 2 O 3 . The catalyst exhibits > 90% NH 3 conversion at 140°C and sustains > 80% N 2 selectivity up to 300°C. Atomic‐resolution microscopy and X‐ray absorption spectroscopy identify L1 0 ‐ordered PtCu intermetallic nanoparticles with Pt‐enriched surfaces, coexisting with CuO x clusters that host isolated Pt single atoms (Pt 1 CuO x ). DRIFTS analysis determines an internal selective catalytic reduction sequence that converts in situ formed NO x to N 2 on the Pt 1 CuO x . Meanwhile, the enhanced low‐temperature activity of the PtCu intermetallic nanoparticles was explained through DFT calculations and microkinetic modeling: electron‐enrichment of Pt by alloying with Cu lowers the upper d‐band edge (ε u ), which weakens *N adsorption and reduces the barrier of the rate‐determining step of N–N coupling. This work proposes a dual‐site design concept of intermetallic‐oxide hybrid catalysts, harnessing ε u engineering of intermetallic sites for activity control, with tandem conversion of in situ formed by‐products on oxide sites for N 2 selectivity control.
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