Energy Efficient Carbon Capture Through Electrochemical PH Swing Regeneration of Amine Solution

Overview

Journal ACS Sustain Chem Eng

Publisher American Chemical Society

Date 2024 May 17

PMID 38757123

Authors

Mu Lin

Clement Ehret

Hubertus V M Hamelers

Annemiek Ter Heijne

Philipp Kuntke

Affiliations

Soon will be listed here.

Abstract

Carbon capture is widely acknowledged as a promising strategy for achieving negative emissions. Electrochemical carbon capture technologies are considered a viable alternative to conventional temperature swing processes. Among these, employing the hydrogen oxidation and hydrogen evolution reactions as a redox couple, along with an ion exchange membrane, offers an effective means of establishing a pH swing for desorbing CO and regenerating the alkaline solvent. However, the practical scalability of this approach is impeded by challenges such as high energy demands resulting from a high pH differential between anodic and cathodic environments and operation with solutions with a low conductivity, required to obtain an acceptable current yield. To address these limitations, this study introduces an innovative anion exchange membrane (AEM)-based electrochemical process for solvent regeneration. Our research demonstrates the advantageous utilization of amines as chemical buffers. Selecting an amine solution with a favorable p (∼7 to 10) helps in maintaining bicarbonate as the predominant carbon species within the system, thereby ensuring a high current yield (>80%) across various operational conditions (current, load ratio, and solution concentration). Furthermore, our analysis indicates that the use of amine solutions effectively reduces the overpotential of the hydrogen evolution reaction due to a lower local pH. This results in a minimum energy requirement of 63 kJ/mol at a current density of 20 A/m to regenerate the solution (MDEA) while maintaining high (>99%) product (CO) purity.

Citing Articles

Continuous Electrochemical Carbon Capture via Redox-Mediated pH Swing─Experimental Performance and Process Modeling.

Sledzik P, Biesheuvel P, Shu Q, Hamelers H, Porada S J Phys Chem Lett. 2025; 16(5):1343-1351.

PMID: 39877949 PMC: 11808779. DOI: 10.1021/acs.jpclett.4c03111.

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