KIEE - The Transactions of the Korean Institute of Electrical Engineers

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C. DeBruler, 2017, Designer Two-Electron Storage Viologen Anolyte Materials for Neutral Aqueous Organic Redox Flow Batteries, Chem, Vol. 3, pp. 961-978

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M. H. Chakrabarti, S. A. Hajimolana, F. S. Mjalli, M. Saleem, I. Mustafa, 2013, Redox Flow Battery for Energy Storage., Arabian Journal for Science and Engineering, Vol. 38, pp. 723-739

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J. Noack, N. Roznyatovskaya, T. Herr, 2015, The Chemistry of Redox-Flow Batteries, Angewandte Chemie-International Edition, Vol. 54, pp. 9775-9808

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F. Pan, Q. Wang, 2015, Redox Species of Redox Flow Batteries: A Review, Molecules, Vol. 20, pp. 20499-20517

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N. X. Wang, 2015, Electrochemical synthesis and characterization of branched viologen derivatives, Electrochimica Acta, Vol. 154, pp. 361-369

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B. Hu, C. DeBruler, Z. Rhodes, T. L. Liu, 2017, Long- Cycling Aqueous Organic Redox Flow Battery (AORFB) toward Sustainable and Safe Energy Storage, Journal of the American Chemical Society, Vol. 139, pp. 1207-1214

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B. Hu, C. Seefeldt, C. DeBruler, T. L. Liu, 2017, Boosting the energy efficiency and power performance of neutral aqueous organic redox flow batteries, Journal of Materials Chemistry A, Vol. 5, pp. 22137-22145

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J. Luo, B. Hu, C. Debruler, T. L. Liu, 2018, A pi-Conjugation Extended Viologen as a Two-Electron Storage Anolyte for Total Organic Aqueous Redox Flow Batteries, Angewandte Chemie-International Edition, Vol. 57, pp. 231-235

10

S. Mehboob, 2018, Enhancing the performance of all-vanadium redox flow batteries by decorating carbon felt electrodes with SnO2 nanoparticles, Applied Energy, Vol. 229, pp. 910-921

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V. Singh, S. Kim, J. Kang, 2019, Aqueous organic redox flow batteries, Nano Research, Vol. 12, pp. 1988-2001

12

S. S. Jang, 2021, Methyl Viologen Anolyte Introducing Nitrate as Counter-Anion for an Aqueous Redox Flow Battery, Journal of the Electrochemical Society, Vol. 168, pp. 100532

13

S. Gentil, D. Reynard, H. H. Girault, 2020, Aqueous organic and redox-mediated redox flow batteries: a review, Current Opinion in Electrochemistry, Vol. 21, pp. 7-13

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J. T. Han, 2020, Two-Electron Storage Viologen for Aqueous Organic Redox Flow Batteries, Chemical Journal of Chinese Universities-Chinese, Vol. 41, pp. 1035-1041

15

P. Sullivan, 2023, Viologen Hydrothermal Synthesis and Structure-Property Relationships for Redox Flow Battery Optimization, Advanced Energy Materials, Vol. 13, pp. 2203919

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E. Pedraza, 2023, Unprecedented Aqueous Solubility of TEMPO and its Application as High Capacity Catholyte for Aqueous Organic Redox Flow Batteries, Advanced Energy Materials, Vol. 13, pp. 2203919

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S. Jin, 2020, Near Neutral pH Redox Flow Battery with Low Permeability and Long-Lifetime Phosphonated Viologen Active Species, Advanced Energy Materials, Vol. 10, pp. 2000100

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J. Y. Ye, 2019, Redox targeting-based flow batteries, Journal of Physics D-Applied Physics, Vol. 52, pp. 443001

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T. Sagara, H. Tahara, 2021, Redox of Viologen for Powering and Coloring, Chemical Record, Vol. 21, pp. 2375-2388

20

X. Wang, J. C. Chai, J. B. Jiang, 2021, Redox flow batteries based on insoluble redox-active materials. A review, Nano Materials Science, Vol. 3, pp. 17-24

21

B. Ambrose, R. P. Naresh, M. Ulaganathan, P. Ragupathy, M. Kathiresan, 2022, Modified viologen as an efficient anolyte for aqueous organic redox flow batteries, Materials Letters, Vol. 314, pp. 131876

22

Q. R. Chen, 2022, Organic Electrolytes for pH-Neutral Aqueous Organic Redox Flow Batteries, Advanced Functional Materials, Vol. 32, pp. 2108777

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M. W. Hu, W. D. Wu, J. Luo, T. L. Liu, 2022, Desymmetrization of Viologen Anolytes Empowering Energy Dense, Ultra Stable Flow Batteries toward Long-Duration Energy Storage, Advanced Energy Materials, Vol. 12, pp. 2202085

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J. Montero, 2022, A Neutral-pH Aqueous Redox Flow Battery Based on Sustainable Organic Electrolytes, Chemelectrochem, Vol. 10, pp. 202201002

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G. Park, W. Lee, Y. Kwon, 2022, Aqueous organic redox flow batteries using naphthoquinone and iodide maintaining pH of electrolytes desirably by adoption of carboxylic acid functionalized carbon nanotube catalyst, International Journal of Energy Research, Vol. 46, pp. 3362-3375

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G. G. Tang, 2022, Designing Robust Two-Electron Storage Extended Bipyridinium Anolytes for pH-Neutral Aqueous Organic Redox Flow Batteries, Jacs Au, Vol. 2, pp. 1214-1222

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W. Lee, K. I. Shim, G. Park, J. W. Han, Y. Kwon, 2023, Rational design of composite supporting electrolyte required for achieving high performance aqueous organic redox flow battery, Chemical Engineering Journal, Vol. 464, pp. 142661

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A. Ohira, T. Funaki, E. Ishida, J. D. Kim, Y. Sato, 2020, Redox-Flow Battery Operating in Neutral and Acidic Environments with Multielectron-Transfer-Type Viologen Molecular Assembly, Acs Applied Energy Materials, Vol. 3, pp. 4377-4383

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H. R. Jiang, 2020, A high power density and long cycle life vanadium redox flow battery, Energy Storage Materials, Vol. 24, pp. 529-540

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W. D. Wu, A. P. Wang, J. Luo, 2023, A Highly Stable, Capacity Dense Carboxylate Viologen Anolyte towards Long-Duration Energy Storage, Angewandte Chemie-International Edition, Vol. 135, pp. 202216662

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M. Chen, L. Liu, P. Y. Zhang, H. N. Chen, 2021, A low- cost and high-loading viologen-based organic electrode for rechargeable lithium batteries, Rsc Advances, Vol. 11, pp. 24429-24435

KIEEThe Transactions of
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The Transactions of the Korean Institute of Electrical Engineers

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KIEEThe Transactions ofthe Korean Institute of Electrical Engineers