Ultrafast synthesis of an efficient urea oxidation electrocatalyst for urea-assisted fast-charging Zn–air batteries and water splitting

IF 32.4 1区材料科学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Energy & Environmental Science Pub Date : 2025-04-30 DOI:10.1039/d5ee01064k

Tongtong Li, Zhiyang Zheng, Zherui Chen, Mengtian Zhang, Zhexuan Liu, Huang Chen, Xiao Xiao, Shaogang Wang, Haotian Qu, Qingjin Fu, Le Liu, Ming Zhou, Boran Wang, Guangmin Zhou

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Abstract

The urea oxidation reaction (UOR) efficiently treats urea-containing wastewater while replacing the high theoretical potential of the oxygen evolution reaction (OER), thereby enabling wastewater valorization. Traditional UOR catalysts are limited by sluggish reaction kinetics and high energy barriers due to non-optimized structures with insufficient active sites and poor charge transfer. Additionally, their complex synthesis increases costs and limits scalability for industrial applications. We addressed these challenges by introducing a 2-second, room-temperature synthesis method for sulfur-doped nickel–iron layered double hydroxide (S-NiFe-LDH). The catalyst's nanostructured surface enhanced mass transfer, and its synthesis required minimal energy and cost. Sulfur doping lowered the catalyst's onset potential, stabilized active sites, and improved charge transfer, significantly enhancing urea oxidation efficiency. Given the critical role of the OER in both water electrolysis and zinc–air battery systems, we applied the catalyst to these two systems, substituting the traditional OER with the UOR. In UOR-assisted water electrolysis, the catalyst achieved a sustained high current density of 100 mA cm⁻² at just 1.47 V over 288 h, demonstrating an energy conversion efficiency in which the electrolyzer consumed only 3.52 kW h of electricity to produce 1 m³ of hydrogen. Additionally, fast-charging UOR-assisted Zn–air batteries maintained stability for over 1931 h. The S-NiFe-LDH catalyst effectively removed urea, mitigating eutrophication from agricultural and industrial effluents. This dual functionality of energy-efficient urea degradation and wastewater purification aligns with global sustainability goals, particularly in terms of clean water access and renewable energy development, providing a scalable and cost-effective solution for clean water and energy.

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尿素辅助快充锌空气电池用高效尿素氧化电催化剂的超快合成及水分解

尿素氧化反应（UOR）在有效处理含尿素废水的同时，取代了理论电位较高的析氧反应（OER），从而实现了废水的增值。传统的UOR催化剂由于结构未优化，活性位不足，电荷转移差，反应动力学迟钝，能量势垒高。此外，它们复杂的合成增加了成本，限制了工业应用的可扩展性。为了解决这些问题，我们引入了一种2秒室温合成硫掺杂镍铁层状双氢氧化物（s - nfe - ldh）的方法。催化剂的纳米结构表面增强了传质，而且它的合成需要最小的能量和成本。硫的掺杂降低了催化剂的起始电位，稳定了活性位点，改善了电荷转移，显著提高了尿素氧化效率。考虑到OER在水电解和锌空气电池系统中的关键作用，我们将催化剂应用于这两个系统，用UOR取代传统的OER。在uor辅助水电解中，催化剂在仅1.47 V的条件下在288 h内实现了100 mA cm - 2的持续高电流密度，证明了能量转换效率，电解槽仅消耗3.52 kW h的电力来产生1 m3的氢气。此外，快速充电的uur辅助锌空气电池保持了超过1931小时的稳定性。S-NiFe-LDH催化剂有效地去除了尿素，减轻了农业和工业废水中的富营养化。这种高效尿素降解和废水净化的双重功能符合全球可持续发展目标，特别是在清洁水获取和可再生能源开发方面，为清洁水和能源提供了可扩展且具有成本效益的解决方案。

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来源期刊

Energy & Environmental Science 化学-工程：化工

CiteScore

50.50

自引率

2.20%

发文量

349

审稿时长

2.2 months

期刊介绍： Energy & Environmental Science, a peer-reviewed scientific journal, publishes original research and review articles covering interdisciplinary topics in the (bio)chemical and (bio)physical sciences, as well as chemical engineering disciplines. Published monthly by the Royal Society of Chemistry (RSC), a not-for-profit publisher, Energy & Environmental Science is recognized as a leading journal. It boasts an impressive impact factor of 8.500 as of 2009, ranking 8th among 140 journals in the category "Chemistry, Multidisciplinary," second among 71 journals in "Energy & Fuels," second among 128 journals in "Engineering, Chemical," and first among 181 scientific journals in "Environmental Sciences." Energy & Environmental Science publishes various types of articles, including Research Papers (original scientific work), Review Articles, Perspectives, and Minireviews (feature review-type articles of broad interest), Communications (original scientific work of an urgent nature), Opinions (personal, often speculative viewpoints or hypotheses on current topics), and Analysis Articles (in-depth examination of energy-related issues).