Radical Compatibility with Nonaqueous Electrolytes and Its Impact on an All-Organic Redox Flow Battery.

Nonaqueous redox flow batteries hold the promise of achieving higher energy density because of the broader voltage window than aqueous systems, but their current performance is limited by low redox material concentration, cell efficiency, cycling stability, and current density. We report a new nonaqueous all-organic flow battery based on high concentrations of redox materials, which shows significant, comprehensive improvement in flow battery performance. A mechanistic electron spin resonance study reveals that the choice of supporting electrolytes greatly affects the chemical stability of the charged radical species especially the negative side radical anion, which dominates the cycling stability of these flow cells. This finding not only increases our fundamental understanding of performance degradation in flow batteries using radical-based redox species, but also offers insights toward rational electrolyte optimization for improving the cycling stability of these flow batteries.

[1]  Wei Wang,et al.  Microporous separators for Fe/V redox flow batteries , 2012 .

[2]  P. Engel,et al.  The reactions of 1-adamantyl radicals with acetonitrile and their bearing on the oxidative decomposition of 1,1'-azoadamantane , 1987 .

[3]  Maria Skyllas-Kazacos,et al.  Progress in Flow Battery Research and Development , 2011 .

[4]  H. Gasteiger,et al.  Stability of superoxide radicals in glyme solvents for non-aqueous Li-O2 battery electrolytes. , 2013, Physical chemistry chemical physics : PCCP.

[5]  B. Dunn,et al.  Electrical Energy Storage for the Grid: A Battery of Choices , 2011, Science.

[6]  Jun Liu,et al.  Electrochemical energy storage for green grid. , 2011, Chemical reviews.

[7]  G. Robertson Pinacol Coupling Reactions , 1991 .

[8]  Lu Zhang,et al.  Molecular engineering towards safer lithium-ion batteries: a highly stable and compatible redox shuttle for overcharge protection , 2012 .

[9]  Haoshen Zhou,et al.  Towards sustainable and versatile energy storage devices: an overview of organic electrode materials , 2013 .

[10]  Fikile R. Brushett,et al.  An All‐Organic Non‐aqueous Lithium‐Ion Redox Flow Battery , 2012 .

[11]  Zhenguo Yang,et al.  A new redox flow battery using Fe/V redox couples in chloride supporting electrolyte , 2011 .

[12]  Charles W. Monroe,et al.  Non-aqueous chromium acetylacetonate electrolyte for redox flow batteries , 2009 .

[13]  C. Low,et al.  Progress in redox flow batteries, remaining challenges and their applications in energy storage , 2012 .

[14]  Jasim Uddin,et al.  Predicting solvent stability in aprotic electrolyte Li-air batteries: nucleophilic substitution by the superoxide anion radical (O2(•-)). , 2011, The journal of physical chemistry. A.

[15]  Lelia Cosimbescu,et al.  TEMPO‐Based Catholyte for High‐Energy Density Nonaqueous Redox Flow Batteries , 2014, Advanced materials.

[16]  Ji‐Guang Zhang,et al.  Effects of Electrolyte Salts on the Performance of Li–O2 Batteries , 2013 .

[17]  Michael P. Marshak,et al.  A metal-free organic–inorganic aqueous flow battery , 2014, Nature.

[18]  Bin Li,et al.  Recent Progress in Redox Flow Battery Research and Development , 2012 .

[19]  Victor E. Brunini,et al.  Semi‐Solid Lithium Rechargeable Flow Battery , 2011 .

[20]  Seok-Gwang Doo,et al.  Non-Aqueous Redox Flow Batteries with Nickel and Iron Tris(2,2′-bipyridine) Complex Electrolyte , 2012 .

[21]  Dong Fang,et al.  Electrochemical Properties of an All-Organic Redox Flow Battery Using 2,2,6,6-Tetramethyl-1-Piperidinyloxy and N-Methylphthalimide , 2011 .

[22]  Hye Ryung Byon,et al.  High‐Performance Lithium‐Iodine Flow Battery , 2013 .