Accelerated dissolution of iridium anode in the presence of organic compounds

Seohyeon Ka; Youngrok Lee; Chulwan Lim; Eung Dab Kim; Hyeon Seok Bang; Woong Kim; Jae Young Choi; Hyung Suk Oh; Woong Hee Lee

doi:10.1038/s41467-025-63992-0

Accelerated dissolution of iridium anode in the presence of organic compounds

Seohyeon Ka, Youngrok Lee, Chulwan Lim, Eung Dab Kim, Hyeon Seok Bang, Woong Kim, Jae Young Choi, Hyung Suk Oh, Woong Hee Lee

Department of Advanced Materials Science and Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

Iridium oxide is commonly used as a catalyst for the oxygen evolution reaction (OER) in various electrolysers. In this study we investigate the impact of organic compounds, such as ethanol, in the accelerated dissolution of iridium oxide, particularly in amorphous form, across a wide pH range. Our findings suggest that organic compounds produced via electrochemical reaction, including CO₂ reduction, can severely compromise the stability of Ir based catalysts during OER. In situ/operando analysis reveals that this degradation is driven by aldehyde oxidation, where dual-lattice oxygen from acetate occupies the oxide lattice of Ir, leading to the collapse of the iridium oxide matrix. This observation highlights the need to find alternative anodic reactions or materials to avoid crossover induced deactivation of the anodic catalyst.

Original language	English
Article number	8946
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-63992-0
State	Published - Dec 2025

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title = "Accelerated dissolution of iridium anode in the presence of organic compounds",

abstract = "Iridium oxide is commonly used as a catalyst for the oxygen evolution reaction (OER) in various electrolysers. In this study we investigate the impact of organic compounds, such as ethanol, in the accelerated dissolution of iridium oxide, particularly in amorphous form, across a wide pH range. Our findings suggest that organic compounds produced via electrochemical reaction, including CO2 reduction, can severely compromise the stability of Ir based catalysts during OER. In situ/operando analysis reveals that this degradation is driven by aldehyde oxidation, where dual-lattice oxygen from acetate occupies the oxide lattice of Ir, leading to the collapse of the iridium oxide matrix. This observation highlights the need to find alternative anodic reactions or materials to avoid crossover induced deactivation of the anodic catalyst.",

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AU - Ka, Seohyeon

AU - Lee, Youngrok

AU - Lim, Chulwan

AU - Kim, Eung Dab

AU - Bang, Hyeon Seok

AU - Kim, Woong

AU - Choi, Jae Young

AU - Oh, Hyung Suk

AU - Lee, Woong Hee

PY - 2025/12

Y1 - 2025/12

N2 - Iridium oxide is commonly used as a catalyst for the oxygen evolution reaction (OER) in various electrolysers. In this study we investigate the impact of organic compounds, such as ethanol, in the accelerated dissolution of iridium oxide, particularly in amorphous form, across a wide pH range. Our findings suggest that organic compounds produced via electrochemical reaction, including CO2 reduction, can severely compromise the stability of Ir based catalysts during OER. In situ/operando analysis reveals that this degradation is driven by aldehyde oxidation, where dual-lattice oxygen from acetate occupies the oxide lattice of Ir, leading to the collapse of the iridium oxide matrix. This observation highlights the need to find alternative anodic reactions or materials to avoid crossover induced deactivation of the anodic catalyst.

AB - Iridium oxide is commonly used as a catalyst for the oxygen evolution reaction (OER) in various electrolysers. In this study we investigate the impact of organic compounds, such as ethanol, in the accelerated dissolution of iridium oxide, particularly in amorphous form, across a wide pH range. Our findings suggest that organic compounds produced via electrochemical reaction, including CO2 reduction, can severely compromise the stability of Ir based catalysts during OER. In situ/operando analysis reveals that this degradation is driven by aldehyde oxidation, where dual-lattice oxygen from acetate occupies the oxide lattice of Ir, leading to the collapse of the iridium oxide matrix. This observation highlights the need to find alternative anodic reactions or materials to avoid crossover induced deactivation of the anodic catalyst.

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DO - 10.1038/s41467-025-63992-0

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VL - 16

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Accelerated dissolution of iridium anode in the presence of organic compounds

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