Chinese Journal of Catalysis ›› 2026, Vol. 85: 193-203.DOI: 10.1016/S1872-2067(26)64962-5
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Kaiyang Zhanga, Huihui Lib, Shuhao Wangb, Rui Yaoa, Jinping Lia,c(
), Chuan Zhaob(
), Guang Liua(
)
Received:2025-09-16
Accepted:2025-10-27
Online:2026-06-18
Published:2026-05-18
Contact:
*E-mail: liuguang@tyut.edu.cn (G. Liu),Supported by:Kaiyang Zhang, Huihui Li, Shuhao Wang, Rui Yao, Jinping Li, Chuan Zhao, Guang Liu. Breaking the activity-stability trade-off of iridium-based catalysts for proton exchange membrane water electrolyzers[J]. Chinese Journal of Catalysis, 2026, 85: 193-203.
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URL: https://www.cjcatal.com/EN/10.1016/S1872-2067(26)64962-5
Fig. 1. (a) Schematic illustration of the synthesis process of Co-IrOx/W. SEM image (b), TEM image (c), HR-TEM image (d), SAED image (e), HAADF-STEM image (f), and corresponding EDS mappings (g) of Co-IrOx/W.
Fig. 2. Raman spectra (a) and High-resolution XPS spectra of Ir 4f (b) of Co-IrOx/W, Co-IrOx, and IrOx/W. (c) Analysis of Ir chemical states in Co-IrO?/W, Co-IrO?, and IrO?/W via Ir 4f XPS spectra. (d) High-resolution XPS spectra of W 4f of Co-IrOx/W and IrOx/W. Ir L3-edge XANES regions (e) and Fourier-transforms of k3-weight Ir L3-edge EXAFS spectra (f) of Co-IrOx/W, Ir foil, and IrO2. W L3-edge XANES regions (g) and Fourier-transforms of k3-weight W L3-edge EXAFS spectra (h) of Co-IrOx/W, W foil, and WO3. (i) Wavelet transforms for the k3-weighted Ir L3-edge and W L3-edge EXAFS signals of Co-IrOx/W.
Fig. 3. LSV curves (a), Overpotential at 10 mA cm-2 and mass activity 1.45 V (b), and Tafel slopes (c) of Co-IrOx/W, Co-IrOx, IrOx/W, and IrO2. (d) TOF values at 250 and 300 mV overpotential of Co-IrOx/W, Co-IrOx, and IrOx/W. (e) CP measurement for Co-IrOx/W and Co-IrOx at different current densities.
Fig. 4. (a) pH dependence of Co-IrOx/W and IrOx/W. (b) Polarization curves of Co-IrOx/W and IrOx/W in the presence or absence of TMAOH in H2SO4 electrolytes. (c) AEM pathways in acidic OER process for Co-IrOx. (d) The comparison of integrated -COHP values for Ir-O hybridization for Co-IrOx and IrOx. (e) Gibbs free-energy and (f) computed DOS diagrams of Co-IrOx and IrOx. (g) Arrhenius plots, (h) Phase peak angles and (i) Linear stored charge versus potential relationships for Co-IrOx/W and IrOx/W.
Fig. 5. (a) CP measurement for Co-IrOx/W and Co-IrOx at 400 mA cm-2, the inset displays the calculated S-number from produced O2/dissolved Ir. (b) Variation of Ir dissolution with time at 400 mA cm-2 for Co-IrOx/W and Co-IrOx. High-resolution XPS spectra of (c) Ir 4f and (d) Co 2p (d) were obtained for Co-IrOx/W and Co-IrOx after electrochemical measurement. (e) High-resolution XPS spectra of O 1s were obtained for Co-IrOx/W before and after electrochemical measurement.
Fig. 6. (a) Schematic diagram of PEMWEs. (b) Polarization curves of PEMWEs using Co-IrOx/W||Pt/C, IrOx/W||Pt/C, and IrO2||Pt/C, inset displays a digital photograph of the PEMWEs device. (c) Nyquist plots of Co-IrOx/W||Pt/C and IrO2||Pt/C at 1.7 V. (d) Breakdown of ohmic, transport, and kinetic losses for Co-IrOx/W||Pt/C. (e) The comparison of ohmic, transport, and kinetic losses for PEMWEs using Co-IrOx/W||Pt/C and IrO2||Pt/C. (f) Chronopotentiometry curve of PEMWEs using Co-IrOx/W||Pt/C and Co-IrOx||Pt/C at 1 A cm-2 current density. (g) Comparison of Co-IrO?/W with reported catalysts in terms of Ir loading and stability.
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