Electrochemistry-Based CO2 Removal Technologies

Author(s)

Biel‐Nielsen, Tessa Lund; Hatton, T Alan; Villadsen, Sebastian NB; Jakobsen, Jan S; Bonde, Jacob L; Spormann, Alfred M; Fosbøl, Philip L; ... Show more Show less

Abstract

Unprecedented increase in atmospheric CO2 levels calls for efficient, sustainable, and cost-effective technologies for CO2 removal, including both capture and conversion approaches. Current CO2 abatement is largely based on energy-intensive thermal processes with a high degree of inflexibility. In this Perspective, it is argued that future CO2 technologies will follow the general societal trend towards electrified systems. This transition is largely promoted by decreasing electricity prices, continuous expansion of renewable energy infrastructure, and breakthroughs in carbon electrotechnologies, such as electrochemically modulated amine regeneration, redox-active quinones and other species, and microbial electrosynthesis. In addition, new initiatives make electrochemical carbon capture an integrated part of Power-to-X applications, for example, by linking it to H2 production. Selected electrochemical technologies crucial for a future sustainable society are reviewed. However, significant further development of these technologies within the next decade is needed, to meet the ambitious climate goals.

Date issued

2023-03-02

URI

https://hdl.handle.net/1721.1/162347

Department

Massachusetts Institute of Technology. Department of Chemical Engineering

Journal

ChemSusChem

Publisher

Wiley

Citation

Biel‐Nielsen, Tessa Lund, Hatton, T Alan, Villadsen, Sebastian NB, Jakobsen, Jan S, Bonde, Jacob L et al. 2023. "Electrochemistry-Based CO2 Removal Technologies." ChemSusChem, 16 (11).

Version: Final published version