Capture and Electrochemical Conversion of CO₂ into Carbon Nanotubes Using Molten Alkali Metal Borates

ECS Meeting Abstracts Pub Date : 2023-08-28 DOI:10.1149/ma2023-01492558mtgabs

Michael Philip Nitzsche, Lev Bromberg, T. Alan Hatton

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Abstract

Molten alkali metal borates have recently shown promise as high-temperature sorbents for capture of CO 2 and acid gases. These molten salt sorbents enable realization of thermodynamic enhancements offered by conventional solid high temperature sorbents while resolving practical challenges such as morphological degradation. Prior studies have focused on regeneration of alkali borates through steam sweeping and thermal cycling. In this work, we demonstrate that mixed sodium-lithium borate salts as CO 2 sorbents can also be regenerated electrochemically, producing valuable multiwalled carbon nanotubes (MWCNT) via electroreduction of captured CO 2 . Effects of cathode materials and operating conditions in CO 2 electroreduction in molten sodium-lithium borate are quantified. By varying relative starting compositions of alkali borates and alkali carbonates, an optimal composition of borates and carbonates is determined, achieving high coulombic efficiencies and significantly higher CO 2 uptake capacities than traditionally employed carbonate salts used for conversion of CO 2 into CNTs in the desirable 550-650°C range.

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利用熔融碱金属硼酸盐捕获和电化学转化CO2为碳纳米管

熔融的碱金属硼酸盐最近显示出作为捕获二氧化碳和酸性气体的高温吸附剂的前景。这些熔盐吸附剂能够实现传统固体高温吸附剂提供的热力学增强，同时解决诸如形态降解等实际挑战。以往的研究主要集中在碱硼酸盐的蒸汽清洗和热循环再生上。在这项工作中，我们证明了混合硼酸钠锂盐作为CO 2吸附剂也可以通过电化学再生，通过电还原捕获的CO 2产生有价值的多壁碳纳米管(MWCNT)。定量研究了正极材料和操作条件对硼酸钠锂液中co2电还原的影响。通过改变碱硼酸盐和碱碳酸盐的相对起始组成，确定了硼酸盐和碳酸盐的最佳组成，在550-650°C范围内实现高库仑效率和比传统碳酸盐盐更高的二氧化碳吸收能力，用于将二氧化碳转化为碳纳米管。

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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