Mixed metal-antimony oxide nanocomposites: low pH water oxidation electrocatalysts with outstanding durability at ambient and elevated temperatures

• Published in: Journal of materials chemistry. A, Materials for energy and sustainability Vol. 9; no. 48; pp. 27468 - 27484
• Main Authors: Luke, Sibimol, Chatti, Manjunath, Yadav, Asha, Kerr, Brittany V, Kangsabanik, Jiban, Williams, Tim, Cherepanov, Pavel V, Johannessen, Bernt, Tanksale, Akshat, MacFarlane, Douglas R, Hocking, Rosalie K, Alam, Aftab, Yella, Aswani, Simonov, Alexandr N
• Format: Journal Article
• Language: English
• Published: Cambridge Royal Society of Chemistry 14.12.2021
• Subjects: Antimony; Antimony oxides; Catalysts; Cobalt; Crystallites; Crystals; Density functional theory; durability; Electrocatalysts; Energy efficiency; films (materials); High temperature; Hybridization; Iridium; Iron; Manganese; Metals; Nanocomposites; Noble metals; Oxidation; oxygen; Ruthenium; Stability analysis; Sulfuric acid; Thin films
• ISSN: 2050-7488; 2050-7496; 2050-7496
• DOI: 10.1039/d1ta07293e

Proton-exchange membrane water electrolysers provide many advantages for the energy-efficient production of H 2 , but the current technology relies on high loadings of expensive iridium at the anodes, which are often unstable in operation. To address this, the present work scrutinises the properties of antimony-metal (Co, Mn, Ni, Fe, Ru) oxides synthesised as flat thin film electrodes by a solution-based method for water electrooxidation in 0.5 M H 2 SO 4 . Among the noble-metal-free catalysts, cobalt-antimony and manganese-antimony oxides demonstrate robust performance under ambient conditions, but slowly lose activity at elevated temperatures. A distinctive feature of the ruthenium-antimony system is its outstanding stability demonstrated herein through up to 8 day-long tests at 80 ± 1 °C, during which the reaction rate of 10 mA cm −2 was maintained at a stable overpotential of 0.34 ± 0.01 V. The S -number for this catalyst is on par with those for the high-performance benchmark Ir-based systems. Density functional theory analysis and detailed physical characterisation reveal that this high stability is supported by the enhanced hybridisation of the oxygen p- and metal d-orbitals induced by antimony and can arise from two distinct structural scenarios: either formation of an antimonate phase, or nanoscale intermixing of metal and antimony oxide crystallites. Stability of the anode catalysts for PEM water electrolysers can be substantially improved by combining the catalytic component with antimony oxides. However, the mechanisms of the catalyst stabilisation differ depending on the active element used.