Scholars@Duke publication: Transforming CO2 to Porous Carbon as a High-Performing Sodium-Ion Battery Anode via Electrochemical Reduction in Molten Carbonates

Transforming CO2 to Porous Carbon as a High-Performing Sodium-Ion Battery Anode via Electrochemical Reduction in Molten Carbonates

Publication , Journal Article

Thapaliya, BP; Ivanov, AS; Gao, S; Chao, HY; Lamm, M; Ganesan, A; Chi, M; Meyer, HM; Sun, XG; Aytug, T; Dai, S; Mahurin, SM

Published in: ACS Sustainable Chemistry and Engineering

May 26, 2025

Published version (DOI)

The prevalence of sodium over lithium prompts exploration of sodium-ion batteries (SIBs) as a viable alternative to lithium-ion batteries (LIBs). Hard carbon has emerged as a promising anode material for SIBs, yet its synthesis poses sustainability challenges and emits pollutants. Here, we introduce CO2-derived porous carbon (graphitic and amorphous) as an anode for SIBs via electrochemical reduction of CO2 in a molten eutectic carbonate salt at a lower temperature that yields materials with controlled microstructure, morphology, and porosity conducive to energy storage. Our CO2-derived carbon demonstrates remarkable specific capacity, superior rate capability, and stable cycling performance as a SIB anode. This innovative strategy harnesses waste CO2 toward advancing SIB energy technology.

Duke Scholars

Author Miaofang Chi Thomas Lord Department of Mechanical Engineering and Materia ...

Published In

ACS Sustainable Chemistry and Engineering

DOI

10.1021/acssuschemeng.4c10896

EISSN

2168-0485

Publication Date

May 26, 2025

Volume

Issue

Start / End Page

7385 / 7394

Related Subject Headings

4004 Chemical engineering
3401 Analytical chemistry
0904 Chemical Engineering
0502 Environmental Science and Management
0301 Analytical Chemistry

Citation

APA

Chicago

ICMJE

MLA

NLM

Thapaliya, B. P., Ivanov, A. S., Gao, S., Chao, H. Y., Lamm, M., Ganesan, A., … Mahurin, S. M. (2025). Transforming CO2 to Porous Carbon as a High-Performing Sodium-Ion Battery Anode via Electrochemical Reduction in Molten Carbonates. ACS Sustainable Chemistry and Engineering, 13(20), 7385–7394. https://doi.org/10.1021/acssuschemeng.4c10896

Thapaliya, B. P., A. S. Ivanov, S. Gao, H. Y. Chao, M. Lamm, A. Ganesan, M. Chi, et al. “Transforming CO2 to Porous Carbon as a High-Performing Sodium-Ion Battery Anode via Electrochemical Reduction in Molten Carbonates.” ACS Sustainable Chemistry and Engineering 13, no. 20 (May 26, 2025): 7385–94. https://doi.org/10.1021/acssuschemeng.4c10896.

Thapaliya BP, Ivanov AS, Gao S, Chao HY, Lamm M, Ganesan A, et al. Transforming CO2 to Porous Carbon as a High-Performing Sodium-Ion Battery Anode via Electrochemical Reduction in Molten Carbonates. ACS Sustainable Chemistry and Engineering. 2025 May 26;13(20):7385–94.

Thapaliya, B. P., et al. “Transforming CO2 to Porous Carbon as a High-Performing Sodium-Ion Battery Anode via Electrochemical Reduction in Molten Carbonates.” ACS Sustainable Chemistry and Engineering, vol. 13, no. 20, May 2025, pp. 7385–94. Scopus, doi:10.1021/acssuschemeng.4c10896.

Thapaliya BP, Ivanov AS, Gao S, Chao HY, Lamm M, Ganesan A, Chi M, Meyer HM, Sun XG, Aytug T, Dai S, Mahurin SM. Transforming CO2 to Porous Carbon as a High-Performing Sodium-Ion Battery Anode via Electrochemical Reduction in Molten Carbonates. ACS Sustainable Chemistry and Engineering. 2025 May 26;13(20):7385–7394.

Published In

ACS Sustainable Chemistry and Engineering

DOI

10.1021/acssuschemeng.4c10896

EISSN

2168-0485

Publication Date

May 26, 2025

Volume

Issue

Start / End Page

7385 / 7394

Related Subject Headings

4004 Chemical engineering
3401 Analytical chemistry
0904 Chemical Engineering
0502 Environmental Science and Management
0301 Analytical Chemistry