Authors
Wen-Yue Lu, Yufu Zhong, Haiyan Wang, Tao Dong, Ruo-Ya Wang, Jing-Ning Gao, Qian Zhu, Jin-Xia Liang, Chun Zhu, Jun Li
Published in
Physical chemistry chemical physics : PCCP. Jul 13, 2026. Epub Jul 13, 2026.
Abstract
Direct C-C coupling of CH4 and CO2 to CH3COOH is a promising 100% atom-economic route, but kinetically hindered by the high inertness of the two reactants. In this work, we systematically evaluated the structural stability of M1/UiO-66-H (M = Fe, Co, Ni, Cu, Ru, Rh, Pd, and Ag) single-atom catalysts (SACs) as well as their adsorption capacities for CH4 and CO2 by DFT calculations. The reaction mechanism was identified to proceed through three consecutive steps, namely, CH4 activation to form CH3*, C-C coupling to generate CH3COO*, and subsequent hydrogen transfer to yield CH3COOH. The rate-determining step (RDS) was determined to be the C-C coupling step, and Rh1/UiO-66-H exhibited a very low activation barrier of 0.56 eV. Microkinetic simulations further demonstrated that Rh1/UiO-66-H achieves a turnover frequency (TOF) of 3.91 × 10-3 s-1 site-1 per active site under industrially relevant conditions (394 K, 7 bar). The high catalytic activity of Rh1/UiO-66-H originates from the regulation of the interaction between the two carbon atoms derived from CH4 and CO2 by the Rh1 single atom, which effectively facilitates the formation of the C-C bond. This catalytic strategy demonstrates the great potential of Rh1/UiO-66-H for the efficient conversion of CO2 and CH4.
PMID:
42438891
Bibliographic data and abstract were imported from PubMed on 13 Jul 2026.
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