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Operando elucidation of hydrogen production mechanisms on sub-nanometric high-entropy metallenes

Y Li, Chun‐Kuo Peng, Yuntong Sun, Nicole L. D. Sui, Yu‐Chung Chang, San‐Yuan Chen, Yingtang Zhou, Yan‐Gu Lin, Jong‐Min Lee

2024Nature Communications62 citationsDOIOpen Access PDF

Abstract

Precise morphological control and identification of structure-property relationships pose formidable challenges for high-entropy alloys, severely limiting their rational design and application in multistep and tandem reactions. Herein, we report the synthesis of sub-nanometric high-entropy metallenes with up to eight metallic elements via a one-pot wet-chemical approach. The PdRhMoFeMn high-entropy metallenes exhibit high electrocatalytic hydrogen evolution performances with 6, 23, and 26 mV overpotentials at −10 mA cm−2 in acidic, neutral, and alkaline media, respectively, and high stability. The electrochemical measurements, theoretical simulations, and operando X-ray absorption spectroscopy reveal the actual active sites along with their dynamics and synergistic mechanisms in various electrolytes. Specially, Mn sites have strong binding affinity to hydroxyl groups, which enhances the water dissociation process at Pd sites with low energy barrier while Rh sites with optimal hydrogen adsorption free energy accelerate hydride coupling, thereby markedly boosting its intrinsic ability for hydrogen production. High-entropy alloys are promising electrocatalysts for multistep and tandem reactions, yet its mechanism remains unclear. Here, the authors address this challenge by using in-situ XAS to reveal the multi-site hydrogen evolution mechanisms on high-entropy metallenes in wide pH electrolytes.

Topics & Concepts

Hydrogen productionEntropy productionProduction (economics)HydrogenNanotechnologyChemistryMaterials scienceStatistical physicsPhysicsOrganic chemistryEconomicsMacroeconomicsHigh Entropy Alloys StudiesAdvanced Materials Characterization TechniquesAdvanced materials and composites
Operando elucidation of hydrogen production mechanisms on sub-nanometric high-entropy metallenes | Litcius