TY - JOUR
T1 - Electrochemical Alkyne Semi-Hydrogenation via Proton-Coupled Electron Transfer on Cu(111) Surface
AU - Tang, Shangfeng
AU - Guo, Na
AU - Chen, Cheng
AU - Yao, Bingqing
AU - Liu, Xuan
AU - Ma, Chi
AU - Liu, Qiyuan
AU - Ren, Shan
AU - He, Chi
AU - Liu, Bin
AU - Li, Xinzhe
PY - 2025/9/8
Y1 - 2025/9/8
N2 - Electrocatalytic alkyne semi-hydrogenation (EASH) powered by renewable electricity using water as a hydrogen donor provides a sustainable alternative to conventional thermocatalysis. However, the current EASH systems predominantly follow hydrogen atom transfer (HAT) pathways, which are prone to over-hydrogenation and at the same time compete with the hydrogen evolution reaction. In this work, we report a proton-coupled electron transfer (PCET) mechanism enabled on Cu(111) surface for highly efficient and selective EASH. Well-defined two-dimensional Cu nanosheets with exposed (111) facets achieve > 98% selectivity for electrochemical semi-hydrogenation of 4-aminophenylacetylene to 4-vinylphenylamine in a membrane electrode assembly reactor. The Cu nanosheets can also efficiently remove 1%–8% alkyne impurities in alkene and exhibit broad substrate scope, stereoselectivity, as well as operational stability. In situ Raman spectroscopy measurements reveal that, during the PCET-mediated EASH, the covalent adsorption of alkynes and their conversion to weakly bound planar intermediates facilitate the EASH process and suppress over-hydrogenation. Interfacial K+-structured and linearly hydrogen-bonded water species further enhance EASH selectivity via proton supply and steric modulation. Radical scavenging and kinetic isotope effect studies, along with theoretical calculations, corroborate a PCET-dominated mechanism on Cu(111) surface. This work establishes a PCET-driven paradigm for selective hydrogenation beyond the conventional HAT pathways. © 2025 Wiley-VCH GmbH.
AB - Electrocatalytic alkyne semi-hydrogenation (EASH) powered by renewable electricity using water as a hydrogen donor provides a sustainable alternative to conventional thermocatalysis. However, the current EASH systems predominantly follow hydrogen atom transfer (HAT) pathways, which are prone to over-hydrogenation and at the same time compete with the hydrogen evolution reaction. In this work, we report a proton-coupled electron transfer (PCET) mechanism enabled on Cu(111) surface for highly efficient and selective EASH. Well-defined two-dimensional Cu nanosheets with exposed (111) facets achieve > 98% selectivity for electrochemical semi-hydrogenation of 4-aminophenylacetylene to 4-vinylphenylamine in a membrane electrode assembly reactor. The Cu nanosheets can also efficiently remove 1%–8% alkyne impurities in alkene and exhibit broad substrate scope, stereoselectivity, as well as operational stability. In situ Raman spectroscopy measurements reveal that, during the PCET-mediated EASH, the covalent adsorption of alkynes and their conversion to weakly bound planar intermediates facilitate the EASH process and suppress over-hydrogenation. Interfacial K+-structured and linearly hydrogen-bonded water species further enhance EASH selectivity via proton supply and steric modulation. Radical scavenging and kinetic isotope effect studies, along with theoretical calculations, corroborate a PCET-dominated mechanism on Cu(111) surface. This work establishes a PCET-driven paradigm for selective hydrogenation beyond the conventional HAT pathways. © 2025 Wiley-VCH GmbH.
KW - Alkyne semi-hydrogenation
KW - Cu(111) surface
KW - Electrocatalysis
KW - Mechanism investigation
KW - Proton-coupled electron transfer
UR - http://www.scopus.com/inward/record.url?scp=105012378179&partnerID=8YFLogxK
UR - https://www.scopus.com/record/pubmetrics.uri?eid=2-s2.0-105012378179&origin=recordpage
U2 - 10.1002/anie.202510192
DO - 10.1002/anie.202510192
M3 - RGC 21 - Publication in refereed journal
C2 - 40757870
SN - 1433-7851
VL - 64
JO - Angewandte Chemie - International Edition
JF - Angewandte Chemie - International Edition
IS - 37
M1 - e202510192
ER -
SDG 7 Affordable and Clean Energy