Nanocluster catalyst driving ampere-level current density in direct seawater electrolysis quantum leap towards sustainable energy

IF 31.6 1区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materials Science and Engineering: R: Reports Pub Date : 2025-09-02 DOI:10.1016/j.mser.2025.101092

Navakoteswara Rao Vempuluru , Yeongjun Yoon , Jyoti Prakash Das , Vijayakumar Elumalai , Anandhan Ayyappan Saj , Hanna Lee , Tae Kyu Kim , Kyeounghak Kim , Arunprasath Sathyaseelan , Perumalsamy Muthukumar , Sang-Jae Kim

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引用次数: 0

Abstract

Direct seawater electrolysis offers a promising route for sustainable hydrogen production, but challenges such as chloride corrosion, high overpotentials, and catalyst instability hinder its scalability. Here, we present a surface-engineered Cu-Ni bimetallic nanocluster catalyst anchored on Ti₃C₂Tₓ MXene via a facile polyvinylpyrrolidone (PVP)-assisted synthesis method. This pioneering design leverages the terminal functional groups (Tx = F, OH, O) of MXene to enhance metal-substrate interactions, optimize intermediate adsorption, and minimize the chloride ions adsorption, enabling efficient and durable seawater splitting. The catalyst achieves ultralow overpotentials of 29 mV (HER) and 250 mV (OER) in ultrapure water, and 49 mV (HER) and 290 mV (OER) in natural seawater at 10 mA cm⁻², closely compute with precious metal-based systems. Remarkably, it delivers a significant current density of 1.5 A cm⁻² at 2.4 V (60 °C) in an anion-exchange membrane (AEM) electrolyzer, demonstrating its potential for industrial-scale hydrogen production. The engineered surface resists chloride-induced corrosion and maintains stability for > 100 h at 100 mA cm⁻² and 70 h at 1000 mA cm⁻² in alkaline seawater. Combined experimental and density functional theory (DFT) analyses reveal the synergistic effects of Cu-Ni nanoclusters and Ti₃C₂Tₓ, elucidating the mechanisms behind enhanced reaction kinetics and durability by In-situ Raman and anticorrosion insights. The scalable, low-cost synthesis method, coupled with seamless integration into photovoltaic-electrolysis systems, achieves a remarkable rate of 1.42 mL/min of H₂ production. This work provides a transformative pathway for sustainable hydrogen production from seawater, addressing global energy and environmental challenges while advancing the fundamental understanding of electrocatalysis.

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纳米团簇催化剂驱动海水直接电解安培级电流密度向可持续能源的量子飞跃

直接海水电解为可持续制氢提供了一条很有前途的途径，但氯化物腐蚀、高过电位和催化剂不稳定性等挑战阻碍了其可扩展性。在这里，我们通过聚乙烯吡咯烷酮（PVP）辅助合成的方法，提出了一种表面工程的Cu-Ni双金属纳米团簇催化剂，锚定在Ti₃C₂TₓMXene上。这种开创性的设计利用了MXene的末端官能团（Tx = F， OH， O）来增强金属与底物的相互作用，优化中间吸附，并最大限度地减少氯离子吸附，从而实现高效和持久的海水分裂。该催化剂在超纯水中达到29 mV （HER）和250 mV （OER）的超低过电位，在自然海水中达到49 mV （HER）和290 mV (OER)（10 mA cm⁻²），与贵金属基体系密切相关。值得注意的是，它在阴离子交换膜（AEM）电解槽中以2.4 V（60°C）提供1.5 a cm⁻²的电流密度，这表明它具有工业规模制氢的潜力。工程表面抵抗氯化物引起的腐蚀，并在碱性海水中保持稳定性>； 100 h（100 mA cm⁻²）和70 h（1000 mA cm⁻²）。结合实验和密度泛函理论（DFT）分析揭示了Cu-Ni纳米团簇和Ti₃C₂Tₓ的协同效应，通过原位拉曼和防腐见解阐明了增强反应动力学和耐久性的机制。这种可扩展、低成本的合成方法，加上与光伏电解系统的无缝集成，实现了1.42 mL/min的H2产率。这项工作为海水可持续制氢提供了一条变革性的途径，解决了全球能源和环境挑战，同时推进了对电催化的基本理解。

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来源期刊

Materials Science and Engineering: R: Reports 工程技术-材料科学：综合

CiteScore

60.50

自引率

0.30%

发文量

审稿时长

34 days

期刊介绍： Materials Science & Engineering R: Reports is a journal that covers a wide range of topics in the field of materials science and engineering. It publishes both experimental and theoretical research papers, providing background information and critical assessments on various topics. The journal aims to publish high-quality and novel research papers and reviews. The subject areas covered by the journal include Materials Science (General), Electronic Materials, Optical Materials, and Magnetic Materials. In addition to regular issues, the journal also publishes special issues on key themes in the field of materials science, including Energy Materials, Materials for Health, Materials Discovery, Innovation for High Value Manufacturing, and Sustainable Materials development.