Issue 45, 2024

Ultrathin carbon layer-coated mesoporous core–shell-type FeP/Fe2O3/C for the hydrogen evolution reaction

Abstract

Due to their low cost and high abundance, iron-based electrocatalysts are considered a promising alternative to platinum for the hydrogen evolution reaction (HER). Herein, we synthesized and evaluated a mesoporous core–shell-type iron phosphide/iron oxide (FeP/Fe3O4) coated with few ultrathin carbon layers as an electrocatalyst for the HER. FeP/Fe3O4 was produced through the partial phosphidation of Fe3O4 mesoporous microspheres. Our findings indicate that even partial phosphidation activates the surface of Fe3O4 for the HER and that FeP/Fe3O4 outperforms pure FeP. Although FeP/Fe3O4 exhibited higher electrochemical impedance and charge-transfer resistance compared to FeP, the FeP/Fe3O4 electrode demonstrated superior performance in both acidic and basic electrolytes. In acidic solution, the η10 values for FeP/Fe3O4/C and FeP/C were approximately 90 and 135 mVRHE, respectively, while in basic medium, they were approximately 303 and 261 mVRHE. In addition, the specific activity of the FeP/Fe3O4 electrode, normalized to the electrochemically active surface area, surpassed that of the FeP electrode. The superior performance of FeP/Fe3O4 was linked to its active centers and turnover frequency (TOF). Specifically, the number of active sites in FeP/Fe3O4 was 1.58 × 10−8 mol, whereas in FeP, it was 1.2 × 10−8 mol. At η = 90 mVRHE, the TOF of the FeP/Fe3O4 electrode was estimated to be 0.47 s−1, approximately 2-fold higher than that of FeP (0.47 s−1). Estimation of the exchange current density (io) and Tafel slopes indicated faster HER kinetics at the catalytic interface of FeP/Fe3O4 (0.18 mA cm−2, 62 mV dec−1) compared to FeP (0.12 mA cm−2, 89 mV dec−1). In addition, the FeP/Fe3O4 electrode maintained a stable current density (20 mA cm−2) for 24 h of continuous operation. Two spin-polarized DFT models were used to obtain information on the Gibbs free energy (ΔGH) and the corresponding adsorption energy (ΔEH). These models included a FeP surface with and without carbon layers, as well as a surface consisting of FeP and Fe3O4. In addition, the calculations offered insights into the stability of the phosphide surface, both with and without carbon layers.

Graphical abstract: Ultrathin carbon layer-coated mesoporous core–shell-type FeP/Fe2O3/C for the hydrogen evolution reaction

Supplementary files

Article information

Article type
Paper
Submitted
21 Apr 2024
Accepted
07 Oct 2024
First published
08 Oct 2024

J. Mater. Chem. A, 2024,12, 31262-31275

Ultrathin carbon layer-coated mesoporous core–shell-type FeP/Fe2O3/C for the hydrogen evolution reaction

A. Adam, M. I. Díez-García, J. R. Morante, M. Ali, Z. Chen, Z. Tian and M. Qamar, J. Mater. Chem. A, 2024, 12, 31262 DOI: 10.1039/D4TA02746A

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