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J. Noack, N. Roznyatovskaya, Tatjana Herr, P. Fischer (2015)
The Chemistry of Redox-Flow Batteries.Angewandte Chemie, 54 34
ffalourd (2019)
Condensed Matter Physics I
M. Duduta, B. Ho, V. Wood, P. Limthongkul, Victor Brunini, W. Carter, Y. Chiang (2011)
Semi‐Solid Lithium Rechargeable Flow BatteryAdvanced Energy Materials, 1
E. Roth, C. Orendorff (2012)
How Electrolytes Influence Battery Safety.The Electrochemical Society interface, 21
Qizhao Huang, Qing Wang (2015)
Next‐Generation, High‐Energy‐Density Redox Flow BatteriesChemPlusChem, 80
Jianlu Zhang, Liyu Li, Z. Nie, Baowei Chen, M. Vijayakumar, Soowhan Kim, Wei Wang, B. Schwenzer, Jun Liu, Z. Yang (2011)
Effects of additives on the stability of electrolytes for all-vanadium redox flow batteriesJournal of Applied Electrochemistry, 41
T. Mohammadi, M. Skyllas-Kazacos (1995)
Characterisation of novel composite membrane for redox flow battery applicationsJournal of Membrane Science, 98
H. Lim, A. Lackner, R. Knechtli (1977)
Zinc‐Bromine Secondary BatteryJournal of The Electrochemical Society, 124
(2007)
Vanadium Redox Flow Batteries: an In-Depth Analysis
Feng Pan, Qing Wang (2015)
Redox Species of Redox Flow Batteries: A ReviewMolecules, 20
Yan Xu, Yuehua Wen, Jie Cheng, Gaoping Cao, Yusheng Yang (2009)
Study on a single flow acid Cd–chloranil batteryElectrochemistry Communications, 11
J. Janek, W. Zeier (2016)
A solid future for battery developmentNature Energy, 1
M. Holland-Cunz, Faye Cording, J. Friedl, U. Stimming (2018)
Redox flow batteries—Concepts and chemistries for cost-effective energy storageFrontiers in Energy, 12
Eugene Beh, Diana Porcellinis, Rebecca Gracia, Kay Xia, R. Gordon, M. Aziz (2017)
A Neutral pH Aqueous Organic–Organometallic Redox Flow Battery with Extremely High Capacity RetentionACS energy letters, 2
J. Friedl, U. Stimming (2013)
Model catalyst studies on hydrogen and ethanol oxidation for fuel cellsElectrochimica Acta, 101
M. Chakrabarti, E. Roberts, Chulheung Bae, M. Saleem (2011)
Ruthenium based redox flow battery for solar energy storageEnergy Conversion and Management, 52
K. Cathro, K. Cedzyńska, D. Constable, P. Hoobin (1986)
Selection of quaternary ammonium bromides for use in zinc/bromine cellsJournal of Power Sources, 18
Y Tanaka M Morita (1988)
Matsumura-inoue, electrochemical oxidation of ruthenium and iron complexes at rotating disk electrode in acetonitrile solutionBulletin of the Chemical Society of Japan, 61
A. Akhil, G. Huff, Aileen Currier, Jacquelynne Hernández, D. Bender, Ben Kaun, D. Rastler, Stella Chen, Andrew Cotter, D. Bradshaw, W. Gauntlett, J. Eyer, Todd Olinsky-Paul, Michelle Ellison, S. Schoenung (2016)
DOE/EPRI Electricity Storage Handbook in Collaboration with NRECA
Kaixiang Lin, Qing Chen, Michael Gerhardt, Liuchuan Tong, Sang Kim, Louise Eisenach, Alvaro Valle, D. Hardee, R. Gordon, M. Aziz, Michael Marshak (2015)
Alkaline quinone flow batteryScience, 349
H. Pratt, N. Hudak, X. Fang, T. Anderson (2013)
A polyoxometalate flow battery
Elena Zanzola, C. Dennison, Alberto Battistel, P. Peljo, H. Vrubel, V. Amstutz, H. Girault (2017)
Redox Solid Energy Boosters for Flow Batteries: Polyaniline as a Case StudyElectrochimica Acta, 235
Brian Huskinson, Michael Marshak, C. Suh, S. Er, Michael Gerhardt, Cooper Galvin, Xudong Chen, Alán Aspuru-Guzik, R. Gordon, M. Aziz (2014)
A metal-free organic–inorganic aqueous flow batteryNature, 505
J. Friedl, I. Markovits, Max Herpich, Guang Feng, A. Kornyshev, U. Stimming (2017)
Interface between an Au(111) surface and an ionic liquid: The influence of water on the double layer capacitance, 4
P. Cappillino, H. Pratt, N. Hudak, N. Tomson, T. Anderson, M. Anstey (2014)
Application of Redox Non‐Innocent Ligands to Non‐Aqueous Flow Battery ElectrolytesAdvanced Energy Materials, 4
A. Sleightholme, Aaron Shinkle, Qinghua Liu, Yongdan Li, C. Monroe, L. Thompson (2011)
Non-aqueous manganese acetylacetonate electrolyte for redox flow batteriesThe Lancet
J. Nørskov, J. Rossmeisl, A. Logadottir, L. Lindqvist, J. Kitchin, T. Bligaard, H. Jónsson (2004)
Origin of the Overpotential for Oxygen Reduction at a Fuel-Cell CathodeJournal of Physical Chemistry B, 108
Y. Lei, Suqin Liu, C. Gao, Xinxing Liang, Zhangxing He, Yun-hua Deng, Zhen He (2013)
Effect of Amino Acid Additives on the Positive Electrolyte of Vanadium Redox Flow BatteriesJournal of The Electrochemical Society, 160
R. Darling, K. Gallagher, F. Brushett, S. Ha, Jeffrey Kowalski (2014)
Pathways to Low Cost Electrochemical Energy Storage: A Comparison of Aqueous and Nonaqueous Flow Batteries
Qinghua Liu, Aaron Shinkle, Yongdan Li, C. Monroe, L. Thompson, A. Sleightholme (2009)
Non-aqueous chromium acetylacetonate electrolyte for redox flow batteriesElectrochemistry Communications, 11
H. Pratt, W. Pratt, X. Fang, N. Hudak, T. Anderson (2014)
Mixed-Metal, Structural, and Substitution Effects of Polyoxometalates on Electrochemical Behavior in a Redox Flow BatteryElectrochimica Acta, 138
H Zhang (2017)
Development and application of high performance^VRB technology. In: IFBF 2017 International Flow Battery ForumIFBF 2017 International Flow Battery Forum; citation_publication_date=2017; citation_id=CR138; citation_author=H Zhang; citation_publisher=Manchester
Aaron Shinkle, A. Sleightholme, L. Griffith, L. Thompson, C. Monroe (2012)
Degradation mechanisms in the non-aqueous vanadium acetylacetonate redox flow batteryJournal of Power Sources, 206
M. Goulet, E. Kjeang (2014)
Co-laminar flow cells for electrochemical energy conversionJournal of Power Sources, 260
B. Schwenzer, Jianlu Zhang, Soowhan Kim, Liyu Li, Jun Liu, Z. Yang (2011)
Membrane development for vanadium redox flow batteries.ChemSusChem, 4 10
S. Hosseiny, M. Saakes, Matthias Wessling (2011)
A polyelectrolyte membrane-based vanadium/air redox flow batteryElectrochemistry Communications, 13
Z. Yang, Jianlu Zhang, M. Kintner-Meyer, Xiaochuan Lu, D. Choi, J. Lemmon, Jun Liu (2011)
Electrochemical energy storage for green grid.Chemical reviews, 111 5
M. Pope, G. Varga (1966)
Heteropoly Blues. I. Reduction Stoichiometries and Reduction Potentials of Some 12-TungstatesInorganic Chemistry, 5
(1995)
Stabilised electrolyte solutions, methods of preparation thereof and redox cells and batteries containing stabilised electrolyte solutions
(2017)
Development and application of high performance VRB technology
Yongrong Dong, H. Kaku, K. Hanafusa, K. Moriuchi, T. Shigematsu (2015)
A Novel Titanium/Manganese Redox Flow Battery, 69
Liyu Li, Soowhan Kim, Wei Wang, M. Vijayakumar, Z. Nie, Baowei Chen, Jianlu Zhang, Guanguang Xia, Jian Hu, G. Graff, Jun Liu, Z. Yang (2011)
A Stable Vanadium Redox‐Flow Battery with High Energy Density for Large‐Scale Energy StorageAdvanced Energy Materials, 1
Bo Yang, Lena Hoober-Burkhardt, F. Wang, G. Prakash, S. Narayanan (2014)
An Inexpensive Aqueous Flow Battery for Large-Scale Electrical Energy Storage Based on Water-Soluble Organic Redox CouplesJournal of The Electrochemical Society, 161
G M Jr Varga M Pope (1966)
Heteropoly bluesI. Reduction stoichiometries and reduction potentials of some 12-tungstates. Inorganic Chemistry, 5
F. Islam, K. Mamun, M. Amanullah (2017)
Smart energy grid design for island countries: challenges and opportunities
Dingchang Lin, Yayuan Liu, Yi Cui (2017)
Reviving the lithium metal anode for high-energy batteries.Nature nanotechnology, 12 3
Qizhao Huang, Hong Li, M. Grätzel, Qing Wang (2013)
Reversible chemical delithiation/lithiation of LiFePO4: towards a redox flow lithium-ion battery.Physical chemistry chemical physics : PCCP, 15 6
Xiaoliang Wei, Wu Xu, M. Vijayakumar, L. Cosimbescu, T. Liu, V. Sprenkle, Wei Wang (2014)
TEMPO‐Based Catholyte for High‐Energy Density Nonaqueous Redox Flow BatteriesAdvanced Materials, 26
M. Armand, J. Tarascon (2008)
Building better batteriesNature, 451
B. Chalamala, Thiagarajan Soundappan, G. Fisher, M. Anstey, V. Viswanathan, M. Perry (2014)
Redox Flow Batteries: An Engineering PerspectiveProceedings of the IEEE, 102
Jie Cheng, Li Zhang, Yusheng Yang, Yuehua Wen, Gaoping Cao, Xindong Wang (2007)
Preliminary study of single flow zinc-nickel batteryElectrochemistry Communications, 9
Zhen Li, Sha Li, Suqin Liu, Ke‐long Huang, D. Fang, Fengchao Wang, Sui Peng (2011)
Electrochemical Properties of an All-Organic Redox Flow Battery Using 2,2,6,6-Tetramethyl-1-Piperidinyloxy and N-MethylphthalimideElectrochemical and Solid State Letters, 14
H. Dewage, Billy Wu, A. Tsoi, V. Yufit, G. Offer, N. Brandon (2015)
A novel regenerative hydrogen cerium fuel cell for energy storage applicationsJournal of Materials Chemistry, 3
(2003)
Occupational Toxicants: Critical Data Evaluation for MAK Values and Classfication of Carcinogens, Band 19, The MAK-Collection for Occupational Health and Safety. Part 1: MAK Value Documentations (DFG)
F. Béguin, V. Presser, A. Balducci, E. Frąckowiak (2014)
Carbons and Electrolytes for Advanced SupercapacitorsAdvanced Materials, 26
K. Vetter, Scripta Technica, S. Bruckenstein, B. Howard (1967)
Electrochemical Kinetics: Theoretical and Experimental Aspects
Rylan Dmello, Jarrod Milshtein, F. Brushett, Kyle Smith (2016)
Cost-driven materials selection criteria for redox flow battery electrolytesJournal of Power Sources, 330
M. Skyllas-Kazacos, C. Menictas, M. Kazacos (1996)
Thermal stability of concentrated V(V) electrolytes in the vanadium redox cellJournal of The Electrochemical Society, 143
Review of Electrical Energy Storage Technologies and Systems and of their Potential for the UK (2004)
//webarchive. nationalarchives.gov.uk/20100919182219/http://www.ensg.gov. uk/assets/dgdti00055.pdf
M. Goulet, O. Ibrahim, Will Kim, E. Kjeang (2017)
Maximizing the power density of aqueous electrochemical flow cells with in operando depositionJournal of Power Sources, 339
Aaron Shinkle, A. Sleightholme, L. Thompson, C. Monroe (2011)
Electrode kinetics in non-aqueous vanadium acetylacetonate redox flow batteriesJournal of Applied Electrochemistry, 41
Qing Chen, Michael Gerhardt, Lauren Hartle, M. Aziz (2016)
A Quinone-Bromide Flow Battery with 1 W/cm2 Power DensityJournal of The Electrochemical Society, 163
Yiyang Liu, Shanfu Lu, Haining Wang, Chun-Shang Yang, Xinrui Su, Yan Xiang (2017)
An Aqueous Redox Flow Battery with a Tungsten–Cobalt Heteropolyacid as the Electrolyte for both the Anode and CathodeAdvanced Energy Materials, 7
S. Oh, C.-W. Lee, D. Chun, Jae-Deok Jeon, J. Shim, Kyoung‐Hee Shin, Jun-Jie Yang (2014)
A metal-free and all-organic redox flow battery with polythiophene as the electroactive speciesJournal of Materials Chemistry, 2
L Li (2012)
Estimation of capital and levelized cost for redox flow batteries
Howey D, Contestabile M, Clague D, Brandon P (2009)
Comparative analysis of battery electric, hydrogen fuel cell and hybrid vehicles in a future sustainable road transport system
P. Morrissey (2000)
Regenesys: a new energy storage technologyInternational Journal of Ambient Energy, 21
Thomas Carney, S. Collins, Jeffrey Moore, F. Brushett (2017)
Concentration-Dependent Dimerization of Anthraquinone Disulfonic Acid and Its Impact on Charge StorageChemistry of Materials, 29
Kaixiang Lin, Rafael Gómez-Bombarelli, Eugene Beh, Liuchuan Tong, Qing Chen, Alvaro Valle, Alán Aspuru-Guzik, M. Aziz, R. Gordon (2016)
A redox-flow battery with an alloxazine-based organic electrolyteNature Energy, 1
Zi-li Xie (2008)
Preliminary Study of Single Flow Zinc-Nickel BatteryJournal of Electrochemistry
Pletcher D. Electrochemical engineering and cell design. In Walsh F C (2014)
Pletcher DPletcher D
(2010)
arpa-e GRIDS program overview
(1985)
Chemical and electrochemical behavior of the Cr(lll)/Cr(ll) half-cell in the iron-chromium redox energy system
M. Aziz, Qing Chen, Michael Gerhardt (2017)
Dissection of the Voltage Losses of an Acidic Quinone Redox Flow Battery
(2004)
Review of Electrical Energy Storage Technologies and Systems and of their Potential for the UK
M Moore M Zhang (2012)
Capital cost sensitivity analysis of an all-vanadium redox-flow batteryJournal of the Electrochemical Society, 159
J. Metzger (1998)
Lösungsmittelfreie organische SynthesenAngewandte Chemie, 110
F. Walsh, D. Pletcher (2014)
Electrochemical Engineering and Cell Design
U. S. Department of Energy Headquarters Advanced Research Projects Agency–Energy (2010)
https://www
M. Perry, R. Darling, R. Zaffou (2013)
High Power Density Redox Flow Battery Cells, 53
Bin Li, Z. Nie, M. Vijayakumar, Guosheng Li, Jun Liu, V. Sprenkle, Wen Wang (2015)
Ambipolar zinc-polyiodide electrolyte for a high-energy density aqueous redox flow batteryNature Communications, 6
J. Saraidaridis, B. Bartlett, C. Monroe (2016)
Spectroelectrochemistry of Vanadium Acetylacetonate and Chromium Acetylacetonate for Symmetric Nonaqueous Flow BatteriesJournal of The Electrochemical Society, 163
Wu Xu, Jiulin Wang, F. Ding, Xilin Chen, E. Nasybulin, Yaohui Zhang, Ji‐Guang Zhang (2014)
Lithium metal anodes for rechargeable batteriesEnergy and Environmental Science, 7
M T O Amanullah (2017)
Smart Energy Grid Design for Island Countries
C. Ding, Huamin Zhang, Xianfeng Li, Tao Liu, Feng Xing (2013)
Vanadium Flow Battery for Energy Storage: Prospects and Challenges.The journal of physical chemistry letters, 4 8
U Stimming (2012)
Investigation on polyoxometalates for the application in redox flow batteries. In: 222th ECS Meet.222th ECS Meet
S. Higashi, S. Lee, Jang-soo Lee, K. Takechi, Yi Cui (2016)
Avoiding short circuits from zinc metal dendrites in anode by backside-plating configurationNature Communications, 7
Yikai Zeng, T. Zhao, L. An, Xuelong Zhou, Lei Wei (2015)
A comparative study of all-vanadium and iron-chromium redox flow batteries for large-scale energy storageJournal of Power Sources, 300
B. Keita, L. Nadjo (1989)
New oxometalate-based materials for catalysis and electrocatalysisMaterials Chemistry and Physics, 22
(2010)
Grid-Scale Rampable Intermittent Dispatchable Storage (GRIDS)
A. Weber, M. Mench, J. Meyers, P. Ross, J. Gostick, Qinghua Liu (2011)
Redox flow batteries: a reviewJournal of Applied Electrochemistry, 41
D. Scamman, G. Reade, E. Roberts (2009)
Numerical modelling of a bromide-polysulphide redox flow battery. Part 1: Modelling approach and validation for a pilot scale systemJournal of Power Sources, 189
G. Soloveichik (2015)
Flow Batteries: Current Status and Trends.Chemical reviews, 115 20
J. Christian, Sean Smith, M. Whittingham, H. Abruña (2007)
Tungsten based electrocatalyst for fuel cell applicationsElectrochemistry Communications, 9
F. Walsh (2001)
Electrochemical technology for environmental treatment and clean energy conversionPure and Applied Chemistry, 73
Toxicology Data Network. U.S. National Library of Medicine. (2017)
7, https://toxnet
B. Scrosati, J. Garche (2010)
Lithium batteries: Status, prospects and futureJournal of Power Sources, 195
Junliang Zhang, M. Vukmirovic, Ye Xu, M. Mavrikakis, R. Adzic (2005)
Controlling the catalytic activity of platinum-monolayer electrocatalysts for oxygen reduction with different substrates.Angewandte Chemie, 44 14
P. Lex, B. Jonshagen (1999)
The zinc/bromine battery system for utility and remote area applicationsPower Engineering Journal, 13
Andinet Ejigu, Peter Greatorex-Davies, D. Walsh (2015)
Room temperature ionic liquid electrolytes for redox flow batteriesElectrochemistry Communications, 54
M. Skyllas-Kazacos (2003)
Novel vanadium chloride/polyhalide redox flow batteryJournal of Power Sources, 124
R. Schweiss, Alexander Pritzl, C. Meiser (2016)
Parasitic Hydrogen Evolution at Different Carbon Fiber Electrodes in Vanadium Redox Flow BatteriesJournal of The Electrochemical Society, 163
Tobias Janoschka, Norbert Martin, M. Hager, U. Schubert (2016)
An Aqueous Redox-Flow Battery with High Capacity and Power: The TEMPTMA/MV System.Angewandte Chemie, 55 46
P. Leung, C. Léon, F. Walsh (2011)
An undivided zinc–cerium redox flow battery operating at room temperature (295 K)Electrochemistry Communications, 13
Igor Derr, M. Bruns, Joachim Langner, A. Fetyan, J. Melke, C. Roth (2016)
Degradation of all-vanadium redox flow batteries (VRFB) investigated by electrochemical impedance and X-ray photoelectron spectroscopy: Part 2 electrochemical degradationJournal of Power Sources, 325
A. Nice (1981)
NASA Redox system development project status, 82
Igor Derr, A. Fetyan, K. Schutjajew, C. Roth (2017)
Electrochemical analysis of the performance loss in all vanadium redox flow batteries using different cut-off voltagesElectrochimica Acta, 224
A. Shah, H. Al-Fetlawi, F. Walsh (2010)
Dynamic modelling of hydrogen evolution effects in the all-vanadium redox flow batteryElectrochimica Acta, 55
M. Tucker, V. Srinivasan, P. Ross, A. Weber (2013)
Performance and cycling of the iron-ion/hydrogen redox flow cell with various catholyte saltsJournal of Applied Electrochemistry, 43
M Skyllas-Kazacos M Rychcik (1988)
Characteristics of a new allvanadium redox flow batteryJournal of Power Sources, 22
Mallory Miller, A. Bourke, Nathan Quill, J. Wainright, R. Lynch, D. Buckley, R. Savinell (2016)
Kinetic Study of Electrochemical Treatment of Carbon Fiber Microelectrodes Leading to In Situ Enhancement of Vanadium Flow Battery EfficiencyJournal of The Electrochemical Society, 163
A. Bond, T. Henderson, D. Mann, T. Mann, W. Thormann, C. Zoski (1988)
A fast electron transfer rate for the oxidation of ferrocene in acetonitrile or dichloromethane at platinum disk ultramicroelectrodesAnalytical Chemistry, 60
R. Marshall, F. Walsh (1985)
A review of some recent electrolytic cell designsSurface Technology, 24
E Santos (2010)
Interfacial Electrochemistry. 2nd ed
M. Ulaganathan, V. Aravindan, Q. Yan, S. Madhavi, M. Skyllas-Kazacos, T. Lim (2016)
Recent Advancements in All‐Vanadium Redox Flow BatteriesAdvanced Materials Interfaces, 3
C. Léon, A. Frías-Ferrer, J. González-garcía, D. Szánto, F. Walsh (2006)
Redox flow cells for energy conversionJournal of Power Sources, 160
Aaron Shinkle, Timothy Pomaville, A. Sleightholme, L. Thompson, C. Monroe (2014)
Solvents and supporting electrolytes for vanadium acetylacetonate flow batteriesJournal of Power Sources, 248
T. Anderson, H. Pratt (2015)
Ionic Liquid Flow Batteries.
S. Ressel, A. Laube, Simon Fischer, A. Chica, Thomas Flower, T. Struckmann (2017)
Performance of a vanadium redox flow battery with tubular cell designJournal of Power Sources, 355
J. Friedl, R. Al-Oweini, Max Herpich, B. Keita, U. Kortz, U. Stimming (2014)
Electrochemical studies of tri-manganese substituted Keggin PolyoxoanionsElectrochimica Acta, 141
(2007)
Vanadium Redox Flow Batteries: an In-Depth Analysis. Palo Alto
A. O’Mahony, D. Silvester, L. Aldous, C. Hardacre, R. Compton (2008)
Effect of Water on the Electrochemical Window and Potential Limits of Room-Temperature Ionic LiquidsJournal of Chemical & Engineering Data, 53
M. Vijayakumar, M. Bhuvaneswari, P. Nachimuthu, B. Schwenzer, Soowhan Kim, Z. Yang, Jun Liu, G. Graff, S. Thevuthasan, J. Hu (2011)
Spectroscopic investigations of the fouling process on Nafion membranes in vanadium redox flow batteriesJournal of Membrane Science, 366
H. Yang, Jong Park, H. Ra, Chang-Soo Jin, Jun-Jie Yang (2016)
Critical rate of electrolyte circulation for preventing zinc dendrite formation in a zinc–bromine redox flow batteryJournal of Power Sources, 325
Dapeng Zhang, Hu Lan, Yongdan Li (2012)
The application of a non-aqueous bis(acetylacetone)ethylenediamine cobalt electrolyte in redox flow batteryJournal of Power Sources, 217
O. Barbieri, M. Hahn, A. Herzog, R. Kötz (2005)
Capacitance limits of high surface area activated carbons for double layer capacitorsCarbon, 43
Feng Pan, Jing Yang, Qizhao Huang, Xingzhu Wang, Hui Huang, Qing Wang (2014)
Redox Targeting of Anatase TiO2 for Redox Flow Lithium‐Ion BatteriesAdvanced Energy Materials, 4
L Eisenach Q Chen (2016)
Cycling analysis of a quinonebromide redox flow batteryJournal of the Electrochemical Society, 163
J. Friedl, C. Bauer, R. Al-Oweini, D. Yu, U. Kortz, H. Hoster, U. Stimming (2012)
Investigation on Polyoxometalates for the Application in Redox Flow Batteries
Stimming U. The importance of electrochemistry for the development of sustainable mobility. In Friedl J (2014)
Bruhns HBruhns H
Sha Li, Ke‐long Huang, Suqin Liu, D. Fang, Xiongwei Wu, Dan Lu, Tao Wu (2011)
Effect of organic additives on positive electrolyte for vanadium redox batteryElectrochimica Acta, 56
Zhijiang Tang (2013)
Characterization Techniques and Electrolyte Separator Performance Investigation for All Vanadium Redox Flow Battery
C. Zoski (2006)
Handbook of Electrochemistry
H. Prifti, Aishwarya Parasuraman, S. Winardi, T. Lim, M. Skyllas-Kazacos (2012)
Membranes for Redox Flow Battery ApplicationsMembranes, 2
J. Friedl, U. Stimming (2014)
The Importance of Electrochemistry for the Development of Sustainable Mobility
M. Holland-Cunz, J. Friedl, U. Stimming (2017)
Anion effects on the redox kinetics of positive electrolyte of the all-vanadium redox flow batteryJournal of Electroanalytical Chemistry
D. Henschler, H. Greim, A. Wild, J. Handwerker-Sharman (1998)
Occupational Toxicants: Critical Data Evaluation for MAK Values and Classification of Carcinogens
S. Maurya, Sung-Hee Shin, Yekyung Kim, S. Moon (2015)
A review on recent developments of anion exchange membranes for fuel cells and redox flow batteriesRSC Advances, 5
G W Reade D P Scamman (2009)
Numerical modelling of a bromide-polysulphide redox flow batteryPart 1: Modelling approach and validation for a pilot-scale system. Journal of Power Sources, 189
Jan Winsberg, T. Hagemann, Tobias Janoschka, M. Hager, U. Schubert (2016)
Redox‐Flow Batteries: From Metals to Organic Redox‐Active MaterialsAngewandte Chemie (International Ed. in English), 56
Zhizhang Yuan, Yinqi Duan, Hongzhang Zhang, Xianfeng Li, Huamin Zhang, I. Vankelecom (2016)
Advanced porous membranes with ultra-high selectivity and stability for vanadium flow batteriesEnergy and Environmental Science, 9
M. Rychcik, M. Skyllas-Kazacos (1987)
Evaluation of electrode materials for vanadium redox cellJournal of Power Sources, 19
J. Greeley, I. Stephens, A. Bondarenko, T. Johansson, H. Hansen, T. Jaramillo, T. Jaramillo, J. Rossmeisl, I. Chorkendorff, J. Nørskov (2009)
Alloys of platinum and early transition metals as oxygen reduction electrocatalysts.Nature chemistry, 1 7
Sarah Roe, C. Menictas, M. Skyllas-Kazacos (2016)
A High Energy Density Vanadium Redox Flow Battery with 3 M Vanadium ElectrolyteJournal of The Electrochemical Society, 163
E. Wiedemann, A. Heintz, R. Lichtenthaler (1998)
Transport properties of vanadium ions in cation exchange membranes:: Determination of diffusion coefficients using a dialysis cellJournal of Membrane Science, 141
(2013)
Electron transfer kinetics of the VO 2+ /VO 2 + -reaction on multi-walled carbon nanotubes
P. Leung, A. Shah, L. Sanz, C. Flox, J. Morante, Qian Xu, M. Mohamed, C. Léon, F. Walsh (2017)
Recent developments in organic redox flow batteries: A critical reviewJournal of Power Sources, 360
J. Weber, Z. Samec, V. Mareček (1978)
The effect of anion adsorption on the kinetics of the Fe3+/Fe2+ reaction on Pt and Au electrodes in HclO4*Journal of Electroanalytical Chemistry, 89
V. Ruiz, C. Blanco, E. Raymundo-Piñero, V. Khomenko, F. Béguin, R. Santamaría (2007)
Effects of thermal treatment of activated carbon on the electrochemical behaviour in supercapacitorsElectrochimica Acta, 52
H. Pratt, Jonathan Leonard, L. Steele, Chad Staiger, T. Anderson (2013)
Copper ionic liquids: Examining the role of the anion in determining physical and electrochemical propertiesInorganica Chimica Acta, 396
E. Sum, M. Skyllas-Kazacos (1985)
A study of the V(II)/V(III) redox couple for redox flow cell applicationsJournal of Power Sources, 15
Yu Zhao, Yu Ding, Yutao Li, Lele Peng, H. Byon, J. Goodenough, Guihua Yu (2015)
A chemistry and material perspective on lithium redox flow batteries towards high-density electrical energy storage.Chemical Society reviews, 44 22
Tobias Janoschka, Norbert Martin, U. Martin, C. Friebe, Sabine Morgenstern, H. Hiller, M. Hager, U. Schubert (2015)
An aqueous, polymer-based redox-flow battery using non-corrosive, safe, and low-cost materialsNature, 527
T. Mohammadi, S. Chieng, M. Kazacos (1997)
Water transport study across commercial ion exchange membranes in the vanadium redox flow batteryJournal of Membrane Science, 133
Jan Winsberg, T. Hagemann, Simon Muench, C. Friebe, Bernhard Häupler, Tobias Janoschka, Sabine Morgenstern, M. Hager, U. Schubert (2016)
Poly(boron-dipyrromethene)—A Redox-Active Polymer Class for Polymer Redox-Flow BatteriesChemistry of Materials, 28
F. Chang, Changwei Hu, Xiaojiang Liu, Lian Liu, Jianwen Zhang (2012)
Coulter dispersant as positive electrolyte additive for the vanadium redox flow batteryElectrochimica Acta, 60
V. Yufit, B. Hale, M. Matian, P. Mazur, N. Brandon (2013)
Development of a Regenerative Hydrogen-Vanadium Fuel Cell for Energy Storage ApplicationsJournal of The Electrochemical Society, 160
M. Huynh, T. Meyer (2007)
Proton-coupled electron transfer.Chemical reviews, 107 11
Wei Wang, Soowhan Kim, Baowei Chen, Z. Nie, Jianlu Zhang, Guanguang Xia, Liyu Li, Z. Yang (2011)
A new redox flow battery using Fe/V redox couples in chloride supporting electrolyteEnergy and Environmental Science, 4
Ke Gong, Q. Fang, Shuang Gu, S. Li, Yushan Yan (2015)
Nonaqueous redox-flow batteries: organic solvents, supporting electrolytes, and redox pairsEnergy & Environmental Science, 8
T S Zhao Y K Zeng (2016)
A low-cost ironcadmium redox flow battery for large-scale energy storageJournal of Power Sources, 330
A. Kremleva, Pablo Aparicio, A. Genest, N. Rösch (2017)
Quantum chemical modeling of tri-Mn-substituted W-based Keggin polyoxoanionsElectrochimica Acta, 231
Y. Matsuda, K. Tanaka, M. Okada, Y. Takasu, M. Morita, T. Matsumura-Inoue (1988)
A rechargeable redox battery utilizing ruthenium complexes with non-aqueous organic electrolyteJournal of Applied Electrochemistry, 18
(1984)
Electrically rechargeable anionically active reduction-oxidation electrical storage-supply system
J. Tessonnier, D. Rosenthal, T. Hansen, C. Hess, M. Schuster, R. Blume, F. Girgsdies, N. Pfänder, O. Timpe, D. Su, R. Schlögl (2009)
Analysis of the structure and chemical properties of some commercial carbon nanostructuresCarbon, 47
L. Vogler (2016)
Electrochemistry In Nonaqueous Solutions
M. Skyllas-Kazacos, M. Rychcik, R. Robins, A. Fane, Martin Green (1986)
New All‐Vanadium Redox Flow CellJournal of The Electrochemical Society, 133
Byunghyun Hwang, Min‐Sik Park, Ketack Kim (2015)
Ferrocene and cobaltocene derivatives for non-aqueous redox flow batteries.ChemSusChem, 8 2
L. Arenas, C. Léon, F. Walsh (2017)
Engineering aspects of the design, construction and performance of modular redox flow batteries for energy storageJournal of energy storage, 11
U. Fischer, R. Saliger, V. Bock, R. Petricevic, J. Fricke (1997)
Carbon Aerogels as Electrode Material in SupercapacitorsJournal of Porous Materials, 4
S. Ramachandran, U. Stimming (2015)
Well to wheel analysis of low carbon alternatives for road trafficEnergy and Environmental Science, 8
L. Thaller (1976)
Electrically rechargeable REDOX flow cell
J. Friedl, U. Stimming (2017)
Determining Electron Transfer Kinetics at Porous ElectrodesElectrochimica Acta, 227
T. Mohammadi, M. Kazacos (1996)
Modification of anion-exchange membranes for vanadium redox flow battery applicationsJournal of Power Sources, 63
M. Morita, Yoshinori Tanaka, Keisuke Tanaka, Y. Matsuda, T. Matsumura-Inoue (1988)
Electrochemical Oxidation of Ruthenium and Iron Complexes at Rotating Disk Electrode in Acetonitrile SolutionBulletin of the Chemical Society of Japan, 61
T. Nguyen, A. Whitehead, G. Scherer, N. Wai, M. Oo, A. Bhattarai, G. Chandra, Zhichuan Xu (2016)
The oxidation of organic additives in the positive vanadium electrolyte and its effect on the performance of vanadium redox flow batteryJournal of Power Sources, 334
R. McCreery (2008)
Advanced carbon electrode materials for molecular electrochemistry.Chemical reviews, 108 7
M P Marder (2010)
Condensed Matter Physics. 2nd ed
Mengqi Zhang, M. Moore, J. Watson, T. Zawodzinski, R. Counce (2012)
Capital Cost Sensitivity Analysis of an All-Vanadium Redox-Flow BatteryECS Transactions
Abstract Electrochemical energy storage is one of the few options to store the energy from intermittent renewable energy sources like wind and solar. Redox flow batteries (RFBs) are such an energy storage system, which has favorable features over other battery technologies, e.g. solid state batteries, due to their inherent safety and the independent scaling of energy and power content. However, because of their low energy-density, low power-density, and the cost of components such as redox species and membranes, commercialised RFB systems like the all-vanadium chemistry cannot make full use of the inherent advantages over other systems. In principle, there are three pathways to improve RFBs and to make them viable for large scale application: First, to employ electrolytes with higher energy density. This goal can be achieved by increasing the concentration of redox species, employing redox species that store more than one electron or by increasing the cell voltage. Second, to enhance the power output of the battery cells by using high kinetic redox species, increasing the cell voltage, implementing novel cell designs or membranes with lower resistance. The first two means reduce the electrode surface area needed to supply a certain power output, thereby bringing down costs for expensive components such as membranes. Third, to reduce the costs of single or multiple components such as redox species or membranes. To achieve these objectives it is necessary to develop new battery chemistries and cell configurations. In this review, a comparison of promising cell chemistries is focused on, be they all-liquid, slurries or hybrids combining liquid, gas and solid phases. The aim is to elucidate which redox-system is most favorable in terms of energy-density, power-density and capital cost. Besides, the choice of solvent and the selection of an inorganic or organic redox couples with the entailing consequences are discussed.
"Frontiers in Energy" – Springer Journals
Published: Jun 1, 2018
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