Local coordination and electronic interactions of Pd/MXene via dual‐atom codoping with superior durability for efficient electrocatalytic ethanol oxidation
Zhangxin Chen,
Fan Jing,
Minghui Luo,
Xiaohui Wu,
Haichang Fu,
Shengwei Xiao,
Binbin Yu,
Dan Chen,
Xianqiang Xiong,
Yanxian Jin
Affiliations
Zhangxin Chen
School of Pharmaceutical and Chemical Engineering Taizhou University Taizhou Zhejiang China
Fan Jing
School of Pharmaceutical and Chemical Engineering Taizhou University Taizhou Zhejiang China
Minghui Luo
School of Pharmaceutical and Chemical Engineering Taizhou University Taizhou Zhejiang China
Xiaohui Wu
School of Pharmaceutical and Chemical Engineering Taizhou University Taizhou Zhejiang China
Haichang Fu
School of Pharmaceutical and Chemical Engineering Taizhou University Taizhou Zhejiang China
Shengwei Xiao
School of Pharmaceutical and Chemical Engineering Taizhou University Taizhou Zhejiang China
Binbin Yu
School of Pharmaceutical and Chemical Engineering Taizhou University Taizhou Zhejiang China
Dan Chen
School of Pharmaceutical and Chemical Engineering Taizhou University Taizhou Zhejiang China
Xianqiang Xiong
School of Pharmaceutical and Chemical Engineering Taizhou University Taizhou Zhejiang China
Yanxian Jin
School of Pharmaceutical and Chemical Engineering Taizhou University Taizhou Zhejiang China
Abstract Catalyst design relies heavily on electronic metal‐support interactions, but the metal‐support interface with an uncontrollable electronic or coordination environment makes it challenging. Herein, we outline a promising approach for the rational design of catalysts involving heteroatoms as anchors for Pd nanoparticles for ethanol oxidation reaction (EOR) catalysis. The doped B and N atoms from dimethylamine borane (DB) occupy the position of the Ti3C2 lattice to anchor the supported Pd nanoparticles. The electrons transfer from the support to B atoms, and then to the metal Pd to form a stable electronic center. A strong electronic interaction can be produced and the d‐band center can be shifted down, driving Pd into the dominant metallic state and making Pd nanoparticles deposit uniformly on the support. As‐obtained Pd/DB–Ti3C2 exhibits superior durability to its counterpart (∼14.6% retention) with 91.1% retention after 2000 cycles, placing it among the top single metal anodic catalysts. Further, in situ Raman and density functional theory computations confirm that Pd/DB–Ti3C2 is capable of dehydrogenating ethanol at low reaction energies.
