Bi-metallic electrochemical deposition on 3D pyrolytic carbon architectures for potential application in hydrogen evolution reaction.

IF 7.4 3区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY Science and Technology of Advanced Materials Pub Date : 2024-10-29 eCollection Date: 2024-01-01 DOI:10.1080/14686996.2024.2421740
Prince Kumar Rai, Amritanshu Singh, Shashwat Bishwanathan, Prashant Kumar Gupta, De-Yi Wang, Monsur Islam, Ankur Gupta
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Abstract

3D printing has emerged as a highly efficient process for fabricating electrodes in hydrogen evolution through water splitting, whereas metals are the most popular choice of materials in hydrogen evolution reactions (HER) due to their catalytic activity. However, current 3D printing solutions face challenges, including high cost, low surface area, and sub-optimal performance. In this work, we introduce metal-deposited 3D printed pyrolytic carbon (PyC) as a facile and cost-effective HER electrode. We adopt an integrated approach of resin 3D printing, pyrolysis, and electrochemical metal deposition. 3D printing of a resin and its subsequent pyrolysis led to 3D complex architectures of the conductive substrate, facilitating the electrochemical metal deposition and leading to layered 3D metal architecture. Both monolayers of metals (such as copper and nickel) and bi-metallic 3D PyC structures are demonstrated. Each metal layer thickness ranges from 6 to10 µm. The metal coatings, particularly the bi-metallic configurations, result in achieving significantly higher mechanical properties under compressive loading and improved electrical properties due to the synergistic contributions from each metal counterpart. The metalized PyC structures are further demonstrated for HER catalysts, contributing to the development of highly efficient and durable catalyst systems for hydrogen production. Among the materials studied here, Ni@Cu bimetallic 3D PyC electrodes are particularly well-suited, demonstrating a low HER overpotential value of 264 mV (100 mA/cm2, KOH (1 M)) with corresponding Tafel slopes of 107 mV/dec, with exceptional stability during a 10 h operation at a high applied current of -50 mA/cm2.

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三维热解碳结构上的双金属电化学沉积在氢进化反应中的潜在应用。
三维打印已成为通过水分裂实现氢进化的高效电极制造工艺,而金属因其催化活性成为氢进化反应(HER)中最受欢迎的材料选择。然而,目前的 3D 打印解决方案面临着高成本、低表面积和性能不理想等挑战。在这项工作中,我们引入了金属沉积三维打印热解碳(PyC)作为一种简便且经济高效的氢演化电极。我们采用了树脂三维打印、热解和电化学金属沉积的综合方法。树脂的三维打印及其随后的热解导致了导电基底的三维复杂结构,从而促进了电化学金属沉积并形成了分层的三维金属结构。我们展示了单层金属(如铜和镍)和双金属三维 PyC 结构。每个金属层的厚度从 6 微米到 10 微米不等。由于每种金属的协同作用,金属涂层(尤其是双金属结构)在压缩负载下的机械性能显著提高,电性能也得到改善。金属化 PyC 结构进一步证明了其在 HER 催化剂中的应用,有助于开发高效耐用的制氢催化剂系统。在本文研究的材料中,Ni@Cu 双金属三维 PyC 电极尤为合适,它的 HER 过电位值低至 264 mV(100 mA/cm2,KOH (1M)),相应的 Tafel 斜率为 107 mV/dec,在 -50 mA/cm2 的高应用电流下工作 10 小时期间具有优异的稳定性。
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来源期刊
Science and Technology of Advanced Materials
Science and Technology of Advanced Materials 工程技术-材料科学:综合
CiteScore
10.60
自引率
3.60%
发文量
52
审稿时长
4.8 months
期刊介绍: Science and Technology of Advanced Materials (STAM) is a leading open access, international journal for outstanding research articles across all aspects of materials science. Our audience is the international community across the disciplines of materials science, physics, chemistry, biology as well as engineering. The journal covers a broad spectrum of topics including functional and structural materials, synthesis and processing, theoretical analyses, characterization and properties of materials. Emphasis is placed on the interdisciplinary nature of materials science and issues at the forefront of the field, such as energy and environmental issues, as well as medical and bioengineering applications. Of particular interest are research papers on the following topics: Materials informatics and materials genomics Materials for 3D printing and additive manufacturing Nanostructured/nanoscale materials and nanodevices Bio-inspired, biomedical, and biological materials; nanomedicine, and novel technologies for clinical and medical applications Materials for energy and environment, next-generation photovoltaics, and green technologies Advanced structural materials, materials for extreme conditions.
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