Interfacial chemistry in the electrocatalytic hydrogenation of CO2 over C-Supported Cu-Based systems

Gianolio, D; Higham, M; Quesne, M; Aramini, M; Xu, R; Large, A; Held, G; Velasco-Velez, JJ; Haevecker, M; Knop-Gericke, A; Genovese, C; Ampelli, C; Schuster, M; Perathoner, S; Centi, G; Catlow, RA; Arrigo, R

Interfacial chemistry in the electrocatalytic hydrogenation of CO2 over C-Supported Cu-Based systems

Gianolio, D; Higham, M; Quesne, M; Aramini, M; Xu, R; Large, A; Held, G; Velasco-Velez, JJ; Haevecker, M; Knop-Gericke, A; Genovese, C; Ampelli, C; Schuster, M; Perathoner, S; Centi, G; Catlow, RA; Arrigo, R

Authors

D Gianolio

M Higham

M Quesne

M Aramini

R Xu

A Large

G Held

JJ Velasco-Velez

M Haevecker

A Knop-Gericke

C Genovese

C Ampelli

M Schuster

S Perathoner

G Centi

RA Catlow

Dr Rosa Arrigo R.Arrigo@salford.ac.uk
Associate Professor/Reader

Abstract

Operando soft and hard X-ray spectroscopic techniques were used in combination with plane-wave density functional theory (DFT) simulations to rationalize the enhanced activities of Zn-containing Cu nanostructured electrocatalysts in the electrocatalytic CO2 hydrogenation reaction. We show that at a potential for CO2 hydrogenation, Zn is alloyed with Cu in the bulk of the nanoparticles with no metallic Zn segregated; at the interface, low reducible Cu(I)–O species are consumed. Additional spectroscopic features are observed, which are identified as various surface Cu(I) ligated species; these respond to the potential, revealing characteristic interfacial dynamics. Similar behavior was observed for the Fe–Cu system in its active state, confirming the general validity of this mechanism; however, the performance of this system deteriorates after successive applied cathodic potentials, as the hydrogen evolution reaction then becomes the main reaction pathway. In contrast to an active system, Cu(I)–O is now consumed at cathodic potentials and not reversibly reformed when the voltage is allowed to equilibrate at the open-circuit voltage; rather, only the oxidation to Cu(II) is observed. We show that the Cu–Zn system represents the optimal active ensembles with stabilized Cu(I)–O; DFT simulations rationalize this observation by indicating that Cu–Zn–O neighboring atoms are able to activate CO2, whereas Cu–Cu sites provide the supply of H atoms for the hydrogenation reaction. Our results demonstrate an electronic effect exerted by the heterometal, which depends on its intimate distribution within the Cu phase and confirms the general validity of these mechanistic insights for future electrocatalyst design strategies.

Journal Article Type	Article
Acceptance Date	Mar 31, 2023
Publication Date	Apr 14, 2023
Deposit Date	May 3, 2023
Publicly Available Date	May 3, 2023
Journal	ACS Catalysis
Electronic ISSN	2155-5435
Publisher	American Chemical Society
Volume	13
Publisher URL	https://doi.org/10.1021/acscatal.3c01288
Additional Information	Funders : CALIPSOplus Projects : EU Framework Program for Research and Innovation HORIZON 2020 Grant Number: 730872