English

Atomistic catalyst polarization stemming hydrogen generation from CH4

Materials Science 2024-12-18 v1 Chemical Physics

Abstract

As the extremely-sized nanocrystals and nanopores, an adatom M and atomic vacancy V exhibit extraordinary capability of catalysis with however little knowledge about the catalyst-reactant interfacial bonding dynamics. With the aid of DFT calculations, we examined the dehydrogenization of a single CH4 molecule catalyzed using the Rh(111,100), W(110), Ru(0001) surfaces, and monolayer graphene, with and without M or V. It is uncovered in the following three components: (i) catalyst polarization due to atomic under- or hetero-coordination raises the valence band of the catalyst by bond contraction and atomistic dipolar MP and vacancy dipolar V formation; (ii) reactant bond elongation by the interplay of the MP-V = H attraction and MP-V = C repulsion with the = denoting the negative pole of the MP-V; and (iii) reactant conversion, i.e., the scale of H-C elongation, the catalyst valence-band shift, the adsorption energy, and the catalytic activity are proportional to the charge quantity of the MP-V whose local electric field matters.

Keywords

Cite

@article{arxiv.2412.12138,
  title  = {Atomistic catalyst polarization stemming hydrogen generation from CH4},
  author = {Sanmei Wang and Yong Zhou and Chunyang Ne and Hengxin Fang and Biao Wang and Chang Q Sun},
  journal= {arXiv preprint arXiv:2412.12138},
  year   = {2024}
}
R2 v1 2026-06-28T20:37:37.984Z