Spectroscopic Visualization of Reversible Hydrogen Spillover Between Palladium and Metal-organic Frameworks Toward Catalytic Semihydrogenation

Overview

Journal Nat Commun

Specialty Biology

Date 2024 Mar 23

PMID 38519485

Authors

Qiaoxi Liu

Wenjie Xu

Hao Huang

Hongwei Shou

Jingxiang Low

Yitao Dai

Wanbing Gong

Youyou Li

Delong Duan

Wenqing Zhang

Yawen Jiang

Guikai Zhang

Dengfeng Cao

Kecheng Wei

Ran Long

Shuangming Chen

Li Song

Yujie Xiong

Affiliations

Soon will be listed here.

Abstract

Hydrogen spillover widely occurs in a variety of hydrogen-involved chemical and physical processes. Recently, metal-organic frameworks have been extensively explored for their integration with noble metals toward various hydrogen-related applications, however, the hydrogen spillover in metal/MOF composite structures remains largely elusive given the challenges of collecting direct evidence due to system complexity. Here we show an elaborate strategy of modular signal amplification to decouple the behavior of hydrogen spillover in each functional regime, enabling spectroscopic visualization for interfacial dynamic processes. Remarkably, we successfully depict a full picture for dynamic replenishment of surface hydrogen atoms under interfacial hydrogen spillover by quick-scanning extended X-ray absorption fine structure, in situ surface-enhanced Raman spectroscopy and ab initio molecular dynamics calculation. With interfacial hydrogen spillover, Pd/ZIF-8 catalyst shows unique alkyne semihydrogenation activity and selectivity for alkynes molecules. The methodology demonstrated in this study also provides a basis for further exploration of interfacial species migration.

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