Indigo as a Low‐Cost Redox‐Active Sorbent for Electrochemically Mediated Carbon Capture

Jayarapu, Krish N.; Mathur, Anmol; Li, Xing; Liu, Andong; Zhang, Lingyu; Kim, Jaeeun; Kim, Hyunah; Kuk, Su Keun; Liu, Yayuan

doi:10.1002/adfm.202402355

Adv Funct Materials

2024

DOI: 10.1002/adfm.202402355

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Indigo as a Low‐Cost Redox‐Active Sorbent for Electrochemically Mediated Carbon Capture

Krish N. Jayarapu,

Anmol Mathur,

Xing Li

et al.

Abstract: Climate change has driven the need for carbon capture to mitigate anthropogenic greenhouse gas emissions, yet current thermochemical methods are hampered by high energy intensities. Electrochemically mediated carbon capture (EMCC) utilizing redox‐active carbon dioxide (CO2) carriers is an attractive alternative for carbon capture. Here, an economical vat dye compound, indigo, is presented, which can reversibly capture and release CO2 upon electrochemical reduction and oxidation, respectively. Electrode and ele… Show more

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Cited by 3 publications

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A mini-review for direct air capture (DAC) and direct ocean capture (DOC) using electrochemical technologies

Li,

Qin,

et al. 2025

Future Batteries

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A mini-review for direct air capture (DAC) and direct ocean capture (DOC) using electrochemical technologies

Li,

Qin,

et al. 2025

Future Batteries

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Advances and Challenges in Membrane-Based Electrochemical Reactors for CO₂ Capture: A Mini-Review

Wang,

Deng

et al. 2024

Ind. Eng. Chem. Res.

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Electrochemical CO 2 capture technologies are increasingly recognized for their flexibility, ability to mitigate CO 2 emissions from various sources, and potential for integration with renewable power sources. Despite their promise, most studies remained at the proof-of-concept stage due to their limitations in stability, CO 2 sorption efficiency, and capacity. This mini-review focuses on recent developments and energy-efficiency comparisons of membrane-based electrochemical reactors for CO 2 capture. We explore the mechanisms and chemical systems underlying pH swing, Faradaic electro-swing, and capacitive swing processes. Additionally, we compare these approaches in terms of applicable systems and energy consumption. We identify key limitations, such as nonideal membrane properties, undesirable electrode reactions, and limitations of redox-active carriers. Finally, we highlight areas for improvement and propose research directions to advance this emerging field, in pursuit of being more competitive and efficient for practical CO 2 capture applications.

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Solid-State Electrochemical Carbon Dioxide Capture by Conductive Metal–Organic Framework Incorporating Nickel Bis(diimine) Units

Liu,

Yang,

Zhou

et al. 2024

J. Am. Chem. Soc.

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This paper presents the first implementation of electrically conductive metal−organic framework (MOF) Ni 3 (2,3,6,7,10,11-hexaiminotriphenylene) 2 (Ni 3 (HITP) 2 ) integrated with nickel bis(diimine) (Ni-BDI) units for efficient solidstate electrochemical carbon dioxide (CO 2 ) capture. The electrochemical cell assembled using Ni 3 (HITP) 2 as working electrodes can reversibly capture and release CO 2 through potential control. A high-capacity utilization of 96% and a Faraday efficiency of 98% have been achieved. The material also exhibits excellent electrochemical stability with its capacity maintained during 50 capture− release cycles and resistance to general interferences, including O 2 , H 2 O, NO 2 , and SO 2 . Capacity utilization of up to 35% is obtained at CO 2 concentrations as low as 1%. The capture of CO 2 at concentrations ranging from 1% to 100% requires exceptionally low energy consumption of only 30.5−72.4 kJ mol −1 . Studies combining spectroscopic experiments and computational approaches reveal that the CO 2 capture and release mechanism involves reversible carbamate formation on the N atom of the Ni-BDI unit in the MOF upon its one-electron redox reaction.

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Indigo as a Low‐Cost Redox‐Active Sorbent for Electrochemically Mediated Carbon Capture

Cited by 3 publications

References 51 publications

A mini-review for direct air capture (DAC) and direct ocean capture (DOC) using electrochemical technologies

A mini-review for direct air capture (DAC) and direct ocean capture (DOC) using electrochemical technologies

Advances and Challenges in Membrane-Based Electrochemical Reactors for CO₂ Capture: A Mini-Review

Solid-State Electrochemical Carbon Dioxide Capture by Conductive Metal–Organic Framework Incorporating Nickel Bis(diimine) Units

Contact Info

Product

Resources

About

Indigo as a Low‐Cost Redox‐Active Sorbent for Electrochemically Mediated Carbon Capture

Cited by 3 publications

References 51 publications

A mini-review for direct air capture (DAC) and direct ocean capture (DOC) using electrochemical technologies

A mini-review for direct air capture (DAC) and direct ocean capture (DOC) using electrochemical technologies

Advances and Challenges in Membrane-Based Electrochemical Reactors for CO2 Capture: A Mini-Review

Solid-State Electrochemical Carbon Dioxide Capture by Conductive Metal–Organic Framework Incorporating Nickel Bis(diimine) Units

Contact Info

Product

Resources

About

Advances and Challenges in Membrane-Based Electrochemical Reactors for CO₂ Capture: A Mini-Review