Internal Architecture and Electrochemical Mechanisms of Redox Flow Batteries

Authors

  • Zhe Wang Silesian University of Technology, Gliwice, Poland Author

Keywords:

Redox Flow Batteries (RFBs), Long-Duration Energy Storage, Ion Exchange Membranes, Reaction Mechanisms, Vanadium Redox Flow Battery (VRFB)

Abstract

Redox Flow Batteries (RFBs) have emerged as a transformative solution for large-scale, long-duration energy storage, addressing the safety and scalability limitations of conventional lithium-ion systems. This paper provides a comprehensive analysis of the internal architecture and electrochemical mechanisms that define RFB performance. By decoupling power and energy capacity through external electrolyte circulation, RFBs offer unique flexibility and an exceptional cycle life exceeding 15,000 cycles. We detail the critical role of the cell stack components, including bipolar plates, carbon-based electrodes, and optimized flow field designs, in minimizing concentration polarization and enhancing mass transport. A significant portion of the study focuses on the separator as the primary gatekeeper of efficiency. We evaluate the technical pathways of membrane materials, ranging from industry-standard perfluorinated sulfonic acid (PFSA) membranes to emerging porous separators and Polymers of Intrinsic Microporosity (PIMs). These materials are assessed based on their ion exchange capacity, area resistance, and ability to mitigate active species crossover. ly, the paper reviews the industrial landscape, highlighting large-scale demonstration projects and the ongoing transition toward low-cost, non-fluorinated materials. By integrating material innovation with system-level optimization, RFBs are poised to serve as the backbone of resilient, stable, and sustainable energy grids.

References

1. A. Alem, P. Poormehrabi, J. Lins, L. Pachernegg-Mair, C. Bandl, V. Ruiz, ... and T. Gutmann, "Monitoring chemical processes in redox flow batteries employing in situ and in operando analyses," Energy & Environmental Science, vol. 18, no. 15, pp. 7373-7401, 2025.

2. Y. Liu, Z. Huang, X. Xie, Y. Liu, J. Wu, Z. Guo, and Q. Huang, "Redox flow battery: Flow field design based on bionic mechanism with different obstructions," Chemical Engineering Journal, vol. 498, p. 155663, 2024.

3. H. Hu, M. Han, J. Liu, K. Zheng, Z. Zou, Y. Mu, ... and T. Zhao, "Strategies for improving the design of porous fiber felt electrodes for all-vanadium redox flow batteries from macro and micro perspectives," Energy & Environmental Science, 2025.

4. L. Ye, S. Qi, T. Cheng, Y. Jiang, Z. Feng, M. Wang, ... and Z. He, "Vanadium redox flow battery: review and perspective of 3D electrodes," ACS Nano, vol. 18, no. 29, pp. 18852-18869, 2024.

5. H. Hu, M. Han, J. Liu, K. Zheng, Z. Zou, Y. Mu, ... and T. Zhao, "Strategies for improving the design of porous fiber felt electrodes for all-vanadium redox flow batteries from macro and micro perspectives," Energy & Environmental Science, 2025.

6. S. Thangarasu, G. Palanisamy, S. Sadhasivam, K. Selvakumar, K. R. E. Neerugatti, and T. H. Oh, "Deciphering the role of 2D graphene oxide nanofillers in polymer membranes for vanadium redox flow batteries," Journal of Materials Chemistry A, vol. 12, no. 19, pp. 11176-11234, 2024.

7. S. Pang, L. Li, Y. Ji, and P. Wang, "A Multielectron and High‐Potential Spirobifluorene‐Based Posolyte for Aqueous Redox Flow Batteries," Angewandte Chemie International Edition, vol. 63, no. 42, p. e202410226, 2024.

8. W. Fang, S. Pan, F. Zhang, Y. Zhao, H. Zhang, and S. Zhang, "A three-dimensional flow-electrochemistry coupling model for optimizing the channel configuration of lithium slurry redox flow battery," Chemical Engineering Journal, vol. 485, p. 149572, 2024.

9. S. V. Modak, W. Shen, S. Singh, D. Herrera, F. Oudeif, B. R. Goldsmith, ... and D. G. Kwabi, "Understanding capacity fade in organic redox-flow batteries by combining spectroscopy with statistical inference techniques," Nature Communications, vol. 14, no. 1, p. 3602, 2023.

10. T. F. Yang, L. Z. Zheng, L. T. Teng, S. Rashidi, and W. M. Yan, "Performance analysis of vanadium redox flow battery with interdigitated flow channel," Thermal Science and Engineering Progress, vol. 47, p. 102360, 2024.

11. T. Cheng, S. Qi, Y. Jiang, L. Wang, Q. Zhu, J. Zhu, ... and Z. He, "Carbon structure regulation strategy for the electrode of vanadium redox flow battery," Small, vol. 20, no. 37, p. 2400496, 2024.

12. S. V. Modak, W. Shen, S. Singh, D. Herrera, F. Oudeif, B. R. Goldsmith, ... and D. G. Kwabi, "Understanding capacity fade in organic redox-flow batteries by combining spectroscopy with statistical inference techniques," Nature Communications, vol. 14, no. 1, p. 3602, 2023.

13. X. Pan, X. Cheng, T. Deng, L. Xia, J. Zhang, Y. Min, ... and Q. Xu, "MOF-derived high-entropy oxide-modified graphite felt for enhanced electrochemical performance in vanadium redox flow batteries," Journal of Materials Science & Technology, vol. 247, pp. 44-54, 2026.

14. Y. Liu, Y. Niu, X. Ouyang, C. Guo, P. Han, R. Zhou, ... and Q. Xu, "Progress of organic, inorganic redox flow battery and mechanism of electrode reaction," Nano Research Energy, vol. 2, no. 4, pp. 1-40, 2023.

15. J. Gao, L. Xia, M. Ou, and Z. A. Tan, "Metal Coordination Compounds for Organic Redox Flow Batteries," Batteries & Supercaps, vol. 7, no. 12, p. e202400434, 2024.

Downloads

Published

2026-02-28

Issue

Vol. 3 (2026): 2nd International Conference on Electronics, Engineering, Computer Science and Applied Development (EESD 2025)

Section

Articles

How to Cite

Wang, Z. (2026). Internal Architecture and Electrochemical Mechanisms of Redox Flow Batteries. Simen Owen Academic Proceedings Series, 3, 340-347. https://simonowenpub.com/index.php/SOAPS/article/view/104