Coupling Electrochemical Alkalinization and Mineral Dissolution for Ambient Removal of Both Influent CO2 and Dissolved Nitrite in Seawater

IF 8.9 2区 环境科学与生态学 Q1 ENGINEERING, ENVIRONMENTAL Environmental Science & Technology Letters Environ. Pub Date : 2024-05-20 DOI:10.1021/acs.estlett.4c00313
Hong-Tao Cong, Xiao-Qiang Yan, Li-Kun Yang*, Yuan Jiang*, Chao Wang, Dongping Zhan, Yan Li and Minhan Dai, 
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Abstract

Marine carbon dioxide removal (mCDR) is increasingly recognized as a potential mitigation pathway to achieve the goals of the Paris Agreement. Among the scalable and cost-effective options for mCDR, ocean alkalinity enhancement (OAE) stands out as a potential eco-friendly option. Herein, a novel OAE strategy on the basis of coupled electrochemical alkalinization and CaCO3 dissolution is developed for the removal of influent CO2 in ambient conditions. The laboratory strategy also considers the additional benefit of converting dissolved nitrite, which can be toxic at high concentrations in seawater. The protons produced in the anodic sector are neutralized by timely dissolution of CaCO3 powders, which converts an equivalent mole of dissolved inorganic carbon. The alkalinity generated in the cathodic sector reacts with influent CO2 to form bicarbonate anions in seawater. As a result, the integrated OAE design produces increased total alkalinity and dissolved inorganic carbon in seawater with a relatively moderate energy consumption of 104.5 kJ/mol of CO2 and high electron efficiency. In addition, the anodic reaction converts nitrite to nitrate. The proof-of-concept module thus provides an eco-beneficial pathway for mCDR. A potential environmental scenario could be the integration of OAE and wastewater treatment in intensive and recirculating marine aquaculture.

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将电化学碱化和矿物溶解耦合起来,在环境中同时去除海水中的二氧化碳和溶解亚硝酸盐
海洋二氧化碳去除(mCDR)越来越被认为是实现《巴黎协定》目标的潜在减排途径。在可扩展且具有成本效益的海洋二氧化碳减排方案中,海洋碱度增强(OAE)作为一种潜在的生态友好型方案脱颖而出。本文在电化学碱化和 CaCO3 溶解耦合的基础上开发了一种新型 OAE 战略,用于在环境条件下去除进水二氧化碳。该实验室策略还考虑了转化溶解的亚硝酸盐的额外好处,亚硝酸盐在海水中浓度过高时可能具有毒性。阳极部门产生的质子通过 CaCO3 粉末的及时溶解得到中和,从而转化为等效摩尔的溶解无机碳。阴极区产生的碱度与流入的二氧化碳反应,在海水中形成碳酸氢根阴离子。因此,集成式 OAE 设计可增加海水中的总碱度和溶解无机碳,能耗相对较低,为 104.5 kJ/mol(二氧化碳),电子效率较高。此外,阳极反应还能将亚硝酸盐转化为硝酸盐。因此,概念验证模块为 mCDR 提供了一条有益于生态的途径。一个潜在的环境方案可能是将 OAE 与集约化循环海水养殖中的废水处理结合起来。
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来源期刊
Environmental Science & Technology Letters Environ.
Environmental Science & Technology Letters Environ. ENGINEERING, ENVIRONMENTALENVIRONMENTAL SC-ENVIRONMENTAL SCIENCES
CiteScore
17.90
自引率
3.70%
发文量
163
期刊介绍: Environmental Science & Technology Letters serves as an international forum for brief communications on experimental or theoretical results of exceptional timeliness in all aspects of environmental science, both pure and applied. Published as soon as accepted, these communications are summarized in monthly issues. Additionally, the journal features short reviews on emerging topics in environmental science and technology.
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