基于石墨烯的氚富集电化学系统

Nuclear Fusion Pub Date : 2024-01-04 DOI:10.1088/1741-4326/ad1af4

R. J. Zabolockis, Matiss Sondars, G. Vaivars, I. Reinholds, Vladimir Gostillo, Vladislav Malgin, Anton Kizilov, A. Lescinskis, Andrei Felsharuk, L. Avotina, A. S. Teimane, E. Sprugis, E. Pajuste

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摘要

本研究基于质子交换膜（PEM）电解池和燃料电池的结合，开发了水相氚富集系统。作为质子交换膜，使用了 NafionTM 和实验室合成的磺化聚醚醚酮膜，为了提高氚分离系数，膜上还增加了石墨烯层。氢进化反应动力学的差异和不同同位素在石墨烯层中的迁移是影响氢同位素分离的驱动因素。在电解和燃料电池阶段，使用不同的膜对分离因子进行了测量。在研究过程中确定了石墨烯对分离效率的促进作用。与其他传统方法相比，拟议方法获得的分离因数明显更高。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Graphene-based electrochemical system for tritium enrichment

In this study, tritium enrichment system in a water phase has been developed based on the combination of a proton exchange membrane (PEM) electrolysis cell and fuel cell. As a PEM NafionTM and laboratory synthesized sulfonated poly ether ether ketone membranes modified with additional graphene layer in order to enhance tritium separation factor was used. Both differences in the kinetics of the hydrogen evolution reaction and transport through the graphene layer of different isotopes are the driving factors expecting to affect the separation of hydrogen isotopes. The separation factor was measured both during the electrolysis and fuel cell stage by using different membranes. The facilitating effect of the graphene on the separation efficiency was determined during the study. Separation factor obtained by the proposed method was evidently higher than by other conventional methods.

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Nuclear Fusion

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