同分异构和亲核加成影响螯合氨基甲酸和螯合酮酸水有机氧化还原流电池的性能

IF 3.2 Q2 CHEMISTRY, PHYSICAL Energy advances Pub Date : 2024-09-05 DOI:10.1039/d4ya00331d

Arumugam Suryaprakash, A. Ramar, Fu Ming Wang, Kefyalew Wagari Guji, Citra Deliana Dewi Sundari, Laurien Merinda

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引用次数: 0

摘要

氧化还原液流电池是一种经济高效的电网级储能解决方案。氧化还原液流电池具有储液器和电极分离的特点，易于调节电解质体积和电极尺寸，从而提高了安全性和可扩展性。在这项研究中，我们探讨了两种有机鳌合物：螯合氨基甲酸（CDA）和螯合onic酸（CDO），它们具有相似的分子量，但在杂原子上存在差异：吡啶酮和吡喃酮。当与 K_4 [Fe^II (CN)_6] 电解质结合使用时，CDA 和 CDO 的半电池电位使它们的理论电池电压分别达到 0.49 V 和 0.48 V。CDA 在碱性介质中稳定放电 17 天，放电容量达 650 mAh/L，且无任何降解。与此相反，CDO 在连续循环中逐渐失去容量。我们通过循环伏安法、1H-NMR 和傅立叶变换红外光谱技术分析了 CDO 的分解机理。分析结果表明，CDA 中的同分异构和 CDO 中的亲核加成对 ARFB 的性能有显著影响。

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Tautomerism and Nucleophilic Addition Influenced Performance on Aqueous Organic Redox Flow Batteries of Chelidamic Acid and Chelidonic Acid

The redox flow battery is a cost-effective solution for grid-scale energy storage. Its special feature of separate reservoirs and electrodes makes it easy to adjust electrolyte volume and electrode size, improving safety and scalability. In this work, we explore two organic anolytes, chelidamic acid (CDA) and chelidonic acid (CDO), which share similar molecular weight but differ in their heteroatoms: pyridone and pyrone. The half-cell potentials of CDA and CDO anolytes enable them to exhibit theoretical cell voltages of 0.49 V and 0.48 V, respectively, when coupled with K_4 [Fe^II (CN)_6] catholyte. CDA demonstrated a stable discharge capacity of 650 mAh/L over 17 days in a basic medium without any degradation. In contrast, CDO gradually lose its capacity over successive cycles. The mechanism for the decomposition of CDO was analysed through cyclic voltammetry, 1H-NMR, and FTIR spectroscopy techniques. The analytical results revealed that there was a significant impact of tautomerization in CDA and nucleophilic addition in CDO on the performance in ARFB.

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来源期刊

Energy advances

CiteScore

1.80

自引率

0.00%

发文量