嵌入从生物废料中提取的掺杂 N 的多孔碳中的高效载氧体 NiFeP(氧)氢氧化物纳米粒子,用于双功能电催化剂。

Chemosphere Pub Date : 2024-10-01 Epub Date: 2024-10-12 DOI:10.1016/j.chemosphere.2024.143486
Madhan Vinu, Kung-Yuh Chiang
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引用次数: 0

摘要

在水分离过程中,为高效氢进化反应(HER)和氧进化反应(OER)开发具有成本效益且易于获得的材料,是提高能源转换系统盈利能力和可持续性的关键一步。本研究介绍了一种从香蕉皮生物废料中合成 NiFeP/NPC OHs 的新方法,这种方法将彻底改变材料科学和电化学领域。金属磷化物以其优异的导电性和催化活性而闻名,使用金属磷化物作为双功能催化剂,结合从香蕉皮生物废料(BPW)中高效合成纳米多孔碳(NPC),可为可持续和具有成本效益的能源转换新时代铺平道路。通过化学活化镍、铁和磷(NiFeP)等不同的孔原形成(氧)氢氧化物(OHs),可以获得具有高密度孔隙和大比表面积的功能性碳质结构。由此产生的材料被命名为 NiFeP/NPC OHs,具有显著的多孔性、高导电性、大表面积和化学稳定性。这些特性使 NiFeP/NPC OHs 特别适用于电催化,在 HER 和 OER 中均表现出卓越的活性。经过优化的 NiFeP/NPC OHs 材料在 10 mA cm-2 的条件下,HER 和 OER 的过电位分别为 93 mV 和 243 mV,过电位非常低,并且在 100 小时内具有很高的耐久性。此外,这种双功能 NiFeP/NPC OHs 电极在碱性溶液中表现出卓越的催化活性和稳定性。这项研究不仅强调了从 BPW 中合成 NPC 的创新性以及 NiFeP/NPC OHs 制备的成本效益,还激发了人们对这种新型合成方法潜力的好奇心。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Highly efficient oxygen carrier NiFeP (oxy) hydroxides nanoparticle embedded in N-doped porous carbon derived from bio-waste for bifunctional electrocatalysts.

Developing cost-effective, readily available materials for efficient hydrogen evolution reaction (HER) and oxygen evolution reaction (OER) in water splitting is a crucial step toward enhancing the profitability and sustainability of energy conversion systems. This research introduces a novel synthesis method for NiFeP/NPC OHs from banana peel bio-waste, a method that could revolutionize the field of materials science and electrochemistry. The use of metallic phosphides, known for their excellent electrical conductivity and catalytic activity, as bifunctional catalysts, combined with the efficient synthesis of nanoporous carbons (NPC) from banana peel bio-waste (BPW), could pave the way for a new era of sustainable and cost-effective energy conversion. By chemically activating different porogens, such as nickel, iron, and phosphorus (NiFeP), to form (oxy) hydroxides (OHs), functional carbonaceous structures with a high density of pores and large specific surface areas can be achieved. The resulting materials, designated as NiFeP/NPC OHs, are characterized by their remarkable porosity, high conductivity, large surface area, and chemical stability. These properties make NiFeP/NPC OHs particularly suitable for electrocatalysis, where they exhibit outstanding activity in both HER and OER. The optimized NiFeP/NPC OHs material shows a very low overpotential of 93 mV for HER and 243 mV for OER at 10 mA cm⁻2 and high durability over 100 h. Moreover, the bifunctional NiFeP/NPC OHs electrode demonstrates exceptional catalytic activity and stability in alkaline solutions. This study not only highlights the innovative synthesis of NPC from BPW and the cost-effective fabrication of NiFeP/NPC OHs but also sparks curiosity about the potential of this novel synthesis method.

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