Issue 14, 2024

Copper-based electrocatalyst for hydrogen evolution in water

Abstract

In aqueous pH 7 phosphate buffer, during controlled potential electrolysis (CPE) at −1.10 V vs. Ag|AgCl the literature square planar copper complex, [CuIILEt]BF4 (1), forms a heterogeneous deposit on the glassy carbon working electrode (GCWE) that is a stable and effective hydrogen evolution reaction (HER) electrocatalyst. Specifically, CPE for 20 hours using a small GCWE (A = 0.071 cm2) gave a turnover number (TON) of 364, with ongoing activity. During CPE the brownish-yellow colour of the working solution fades, and a deposit is observed on the small GCWE. Repeating this CPE experiment in a larger cell with a larger GCWE (A = 2.7 cm2), connected to a gas chromatograph, resulted in a TON of 2628 after 2.6 days, with FE = 93%, and with activity ongoing. After this CPE, the working solution had faded to nearly colourless, and visual inspection of the large GCWE showed a material had deposited on the surface. In a ‘rinse and repeat test’, this heterogeneous deposit was used for further CPE, in a freshly prepared working solution minus fresh catalyst, which resulted in similar ongoing HER activity to before, consistent with the surface deposited material being the active HER catalyst. EDS, PXRD and SEM analysis of this deposit shows that copper and oxygen are the main components present, most likely comprising copper and copper(I) oxide ((Cu2O)n) formed from 1. The use of 1 leads to a deposit that is more catalytically active than that formed when starting with a simple copper salt (control), likely due to it forming a more robustly attached deposit, which also enables the observed long-lived catalytic activity.

Graphical abstract: Copper-based electrocatalyst for hydrogen evolution in water

Supplementary files

Article information

Article type
Paper
Submitted
24 Jan 2024
Accepted
07 Mar 2024
First published
11 Mar 2024

Dalton Trans., 2024,53, 6207-6214

Copper-based electrocatalyst for hydrogen evolution in water

A. M. Abudayyeh, M. S. Bennington, J. Hamonnet, A. T. Marshall and S. Brooker, Dalton Trans., 2024, 53, 6207 DOI: 10.1039/D4DT00224E

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