Comparative Analysis of Synthesis Routes for Antimony‐Doped Tin Oxide‐Supported Iridium and Iridium oxide Catalysts for OER in PEM Water Electrolysis

Comparative Analysis of Synthesis Routes for Antimony‐Doped Tin Oxide‐Supported Iridium and Iridium oxide Catalysts for OER in PEM Water Electrolysis

This study investigates and compares four different deposition methods for an iridium‐based catalyst on antimony‐doped tin oxide support for oxygen evolution reaction in water electrolysis. Different synthesis routes often lead to varying properties of the resulting catalyst and can result in perfor...

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Bibliographic Details
Published in:Advanced materials interfaces Vol. 10; no. 15
Main Authors: Gollasch, Marius, Schmeling, Jasmin, Harms, Corinna, Wark, Michael
Format: Journal Article
Language:English
Published: Weinheim John Wiley & Sons, Inc 01-05-2023
Wiley-VCH
Subjects:
Antimony
antimony tin oxide
Catalysts
Chemical composition
Chemical reduction
Chemical synthesis
Controllability
Deposition
Electrochemical analysis
Electrolysis
Heat treatment
Iridium
oxygen evolution reaction
Oxygen evolution reactions
proton exchange membrane
synthesis comparison
Tin
Tin oxides
water electrolysis
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Summary:This study investigates and compares four different deposition methods for an iridium‐based catalyst on antimony‐doped tin oxide support for oxygen evolution reaction in water electrolysis. Different synthesis routes often lead to varying properties of the resulting catalyst and can result in performance disparities. Here, some of the most prominent methods are carried out on the same support material and evaluated with special focus on the deposition yield of Ir and thus cost efficiency along with electrochemical performance. The catalysts are also assessed based on their chemical composition, namely Ir or IrO2‐based, with an additional thermal treatment to convert Ir to IrO2 species. The chosen synthesis routes result in different Ir species to obtain tetragonal IrO2 a modified Adams fusion approach delivers the best controllable and highest Ir loading and thus superior electrochemical performance. As far as metallic Ir catalysts are concerned, a wet‐chemical reduction‐based synthesis results in the most desirable catalyst, which however falls behind the Adams fusion catalyst upon thermal treatment to IrO2. The work in this study is a comprehensive analysis of different synthesis influences and recommends practices for laboratory‐based syntheses and an outlook on industrial viability. This study provides an overview and comparison of different Ir catalyst synthesis methods for metallic Ir/IrOx and rutil‐IrO2 phases along with an in‐depth characterization of them all. Furthermore, the methods are assessed and recommended in terms of ease of use, reliability, and performance both on laboratory and industrial scales.
ISSN:2196-7350
2196-7350
DOI:10.1002/admi.202300036