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Machine-learning-accelerated design of high-performance platinum intermetallic nanoparticle fuel cell catalysts

Peng Yin, Xiangfu Niu, Shuo-Bin Li, Kai Chen, Xi Zhang, Ming J. Zuo, Liang Zhang, Hai‐Wei Liang

2024Nature Communications109 citationsDOIOpen Access PDF

Abstract

Abstract Carbon supported PtCo intermetallic alloys are known to be one of the most promising candidates as low-platinum oxygen reduction reaction electrocatalysts for proton-exchange-membrane fuel cells. Nevertheless, the intrinsic trade-off between particle size and ordering degree of PtCo makes it challenging to simultaneously achieve a high specific activity and a large active surface area. Here, by machine-learning-accelerated screenings from the immense configuration space, we are able to statistically quantify the impact of chemical ordering on thermodynamic stability. We find that introducing of Cu/Ni into PtCo can provide additional stabilization energy by inducing Co-Cu/Ni disorder, thus facilitating the ordering process and achieveing an improved tradeoff between specific activity and active surface area. Guided by the theoretical prediction, the small sized and highly ordered ternary Pt 2 CoCu and Pt 2 CoNi catalysts are experimentally prepared, showing a large electrochemically active surface area of ~90 m 2 g Pt ‒1 and a high specific activity of ~3.5 mA cm ‒2 .

Topics & Concepts

IntermetallicProton exchange membrane fuel cellMaterials scienceCatalysisPlatinumTernary operationNanoparticleFuel cellsChemical engineeringElectrochemistryParticle sizeOxygen reduction reactionNanotechnologyMetallurgyComputer scienceAlloyElectrodeChemistryPhysical chemistryProgramming languageBiochemistryEngineeringElectrocatalysts for Energy ConversionFuel Cells and Related MaterialsMachine Learning in Materials Science
Machine-learning-accelerated design of high-performance platinum intermetallic nanoparticle fuel cell catalysts | Litcius