氧化还原
醌
水溶液
化学
机制(生物学)
化学工程
组合化学
光化学
有机化学
认识论
工程类
哲学
作者
José Eduardo dos Santos Clarindo,Rafael N. P. Colombo,Graziela C. Sedenho,Luana Cristina Italiano Faria,Thiago Bertaglia,Filipe C. D. A. Lima,Roberto da Silva Gomes,Michael J. Aziz,Frank N. Crespilho
标识
DOI:10.1021/acssuschemeng.3c08218
摘要
Symmetric all-quinone aqueous redox flow batteries (SQA-RFBs), in which the same quinone derivative is used as the electroactive compound in the negative and positive electrolytes, thereby obviating the need for a species-selective membrane, have been pursued as a potentially cost-effective and sustainable technology for stationary-electrical energy storage. Molecular decomposition during redox activity has frustrated all symmetric organic aqueous RFB development attempts. We used in situ/operando spectroelectrochemistry and density functional theory calculations to demonstrate that during the redox reaction of alizarin red S (ARS), a promising quinone for SQA-RFBs, intramolecular electronic oscillations form positively charged intermediates. Electrodes functionalized with net negative charge stabilize these intermediates via a hybrid adsorptive–diffusive electrochemical reaction mechanism, thereby enabling the cycling of the SQA-RFB. To understand the mechanism, spectroelectrochemical studies were performed on a series of electrodes with and without this functionalization. We report the performance of the first membraneless SQA-RFB prototype, containing ARS in the electrolyte storage reservoirs and instrumented with a reference electrode to evaluate the evolution of the half-cell potentials.
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