과제정보
이 논문은 정부(교육부)의 재원으로 한국연구재단의 지원(2022RIS-005)와 정부(교육부)의 재원으로 한국연구재단의 지원(No.2021R1l1A3060236)에 의하여 연구하였음.
참고문헌
- J. Mitali, S. Dhinakaran, and A. A. Mohamad, Energy storage systems: A review, Energy Storage Sav., 1, 166-216 (2022).
- T. Feng, H. Wang, Y. Liu, J. Zhang, Y. Xiang, and S. Lu, A redox flow battery with high capacity retention using 12-phosphotungstic acid/iodine mixed solution as electrolytes, J. Power Sources, 436, 226831 (2019).
- I. N. Gumerova and A. Rompel, Synthesis, structures and applications of electron-rich polyoxometalates, Nat. Rev. Chem., 2, 0112 (2018).
- K. L. Hawthorne, J. S. Wainright, and R. F. Savinell, Studies of iron-ligand complexes for an all-iron flow battery application, J. Electrochem. Soc., 161, A1662-A1671 (2014).
- S. Belongia, X. Wang, and X. Zhang, Progresses and perspectives of all-iron aqueous redox flow batteries, Adv. Funct. Mater., 34, 2302077 (2024).
- Alfonso Saez, V. Montiel, and A. Aldaz, An acid-base electrochemical flow battery as energy storage system, Int. J. Hydrog. Energy, 41, 17801-17806 (2016).
- B. S. Jayathilake, E. J. Plichta, M. A. Hendrickson, and S. R. Narayanan, Improvements to the coulombic efficiency of the iron electrode for an all-iron redox-flow battery, J. Electrochem. Soc., 165, A1630-A1638 (2018).
- X. Liu, T. Li, Z. Yuan, and X. Li, Low-cost all-iron flow battery with high performance towards long-duration energy storage, J. Energy Chem., 73, 445-451 (2022).
- Y. Cao, J.-J. J. Chen, and M. A. Barteau, Systematic approaches to improving the performance of polyoxometalates in non-aqueous redox flow batteries, J. Energy Chem., 50, 115-124 (2020).
- C. Xie, Y. Duan, W. Xu, H. Zhang, and X. Li, A low-cost neutral zinc-iron flow battery with high energy density for stationary energy storage, Angew. Chem. Int. Ed., 56, 14953-14957 (2017).
- H. D. Pratt III , N. S. Hudak, X. Fang, and T. M. Anderson, A polyoxometalate flow battery, J. Power Sources, 236, 259-264 (2013).
- J. Friedl, M. V. Holland-Cunz, F. Cording, F. L. Pfanschilling, C. Wills, W. McFarlane, B. Schricker, R, Fleck, H. Wolfschmidt, and U. Stimming, Asymmetric polyoxometalate electrolytes for advanced redox flow batteries, Energy Environ. Sci., 11, 3010-3018 (2018).
- N. Elgrishi, K. J. Rountree, B. D. McCarthy, E. S. Rountree, T. T. Eisenhart, and J. L. Dempsey, A practical beginner's guide to cyclic voltammetry, J. Chem. Educ., 95, 197-206 (2018).
- H. E. Lee, D. E. Kim, C. J. Kim, and T. Kim, A Study on the electrochemical performance of Fe-V chloric/sulfuric mixed acid redox flow battery depending on electrode activation temperature, Appl. Chem. Eng., 31, 639-645 (2020).
- S. Xiao, L. Yu, L. Wu, L. Liu, X. Qiu, and J. Xi, Broad temperature adaptability of vanadium redox flow battery-Part 1: Electrolyte research, Electrochim. Acta, 187, 525-534 (2016).
- S. E. Waters, B. H. Robb, and M. P. Marshak, Effect of chelation on iron-chromium redox flow batteries, ACS Energy Lett., 5, 1758-1762 (2020).
- J. Liu, S. Liu, Z. He, H. Han, and Y. Chen, Effects of organic additives with oxygen-and nitrogen-containing functional groups on the negative electrolyte of vanadium redox flow battery, Electrochim. Acta, 130, 314-321 (2014).
- Y. J. Cho and B. W. Kwon, Relationship between concentration and performance of supporting electrolyte of redox flow battery using polyoxometalate, Appl. Chem. Eng., 34, 175-179 (2023).
- H. E. Lee, D. T. Linh, W. K. Lee, and T. Kim, Study on the improvement of electrochemical performance by controlling the surface characteristics of the oxygen electrode porous transport layer for proton exchange membrane water electrolysis, Appl. Chem. Eng., 32, 332-339 (2021).