Molecular engineering of organic electroactive materials for redox flow batteries

Ding, Yu; Zhang, Shun; Zhou, Yangen; Yu, Guihua

doi:10.1039/c7cs00569e

Cited by 477 publications

(467 citation statements)

References 201 publications

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“…Investigations into ferrocene compounds as redox active materials continue to grow . Recently, attention has turned to the use of ferrocenes as possible components in redox flow battery (RFB) applications, arising from the desire to produce new chemical compounds for the low cost and scalable storage of energy. Among transition metal‐based compounds, ferrocenes have many notable properties as RFB components, ranging from their relative low cost and ease of synthesis to their stabilities and electrochemical reversibility in a variety of media.…”

Section: Figurementioning

confidence: 99%

Cation‐Anion Redox Switching in an All‐Ferrocene Salt

et al. 2018

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Section: Figurementioning

confidence: 99%

Cation‐Anion Redox Switching in an All‐Ferrocene Salt

et al. 2018

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“…[1] Although much work has focused on the development of FB technologies,l ow energy densities,h igh cost have hindered their further commercialization. [2][3][4] Even though the recent development of non-aqueous systems has increased voltage output, [5] energy densities,the FBs are currently significantly limited by the low solubility. [6] Regarding the energy density, zinc-based aqueous FBs are very appealing because of the low cost of zinc and the elimination of electrolyte volume.…”

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confidence: 99%

A Long Cycle Life, Self‐Healing Zinc–Iodine Flow Battery with High Power Density

et al. 2018

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A zinc-iodine flow battery (ZIFB) with long cycle life, high energy, high power density, and self-healing behavior is prepared. The long cycle life was achieved by employing a low-cost porous polyolefin membrane and stable electrolytes. The pores in the membrane can be filled with a solution containing I that can react with zinc dendrite. Therefore, by consuming zinc dendrite, the battery can self-recover from micro-short-circuiting resulting from overcharging. By using KI, ZnBr , and KCl as electrolytes and a high ion-conductivity porous membrane, a very high power density can be achieved. As a result, a ZIFB exhibits an energy efficiency (EE) of 82 % at 80 mA cm , which is 8 times higher than the currently reported ZIFBs. Furthermore, a stack with an output of 700 W was assembled and continuously run for more than 300 cycles. We believe this ZIFB can lead the way to development of new-generation, high-performance flow batteries.

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“…[1,2] Ap romising candidate for grid-scale energy storage is the redox flow battery (RFB) technology,w hereby solutions of electroactivem aterials are pumped to/frome xternal tanks to the electrode interface for charging/discharging. [11] Metal-ligandc oordination complexes are good candidates for nonaqueous RFBelectrolytes as they can be stable in multiple oxidation states and have high solubility in organic solvents.F urthermore, careful choice of metal ion as well as modification of the ligand scaffold (e.g.,s olubilizing groups, denticity,d onorg roups) can allow for fine tuning of the desired properties for RFB applications. [6][7][8][9][10] Acetonitrile (MeCN) is an attractive solvent for nonaqueous RFBs, andi st he main solvento f choice here, owing to its wide ( % 5V)e lectrochemical window as well as low viscosity (0.34 vs. 0.89 MPa sfor water) and moderate dielectric constant(35.9 vs. 78.4 for water).…”

Section: Introductionmentioning

confidence: 99%

Dithiolene Complexes of First‐Row Transition Metals for Symmetric Nonaqueous Redox Flow Batteries

2019

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Five metal complexes of the dithiolene ligand maleonitriledithiolate (mnt2−) with M=V, Fe, Co, Ni, Cu were studied as redox‐active materials for nonaqueous redox flow batteries (RFBs). All five complexes exhibit at least two redox processes, making them applicable to symmetric RFBs as single‐species electrolytes, that is, as both negolyte and posolyte. Charge–discharge cycling in a small‐scale RFB gave modest performances for [(tea)2Vmnt], [(tea)2Comnt], and [(tea)2Cumnt] whereas [(tea)Femnt] and [(tea)2Nimnt] (tea=tetraethylammonium) failed to hold any significant capacity, indicating poor stability. Independent negolyte‐ and posolyte‐only battery cycling of a single redox couple, as well as UV/Vis spectroscopy, showed that for [(tea)2Vmnt] the negolyte is stable whereas the posolyte is unstable over multiple charge–discharge cycles; for [(tea)2Comnt], [(tea)2Nimnt], and [(tea)2Cumnt], the negolyte suffers rapid capacity fading although the posolyte is more robust. Identifying a means to stabilize Vmnt 3−/2− as a negolyte, and Comnt 2−/1−, Nimnt 2−/1−, and Cumnt 2−/1− as posolytes could lead to their use in asymmetric RFBs.

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Molecular engineering of organic electroactive materials for redox flow batteries

Cited by 477 publications

References 201 publications

Cation‐Anion Redox Switching in an All‐Ferrocene Salt

Cation‐Anion Redox Switching in an All‐Ferrocene Salt

A Long Cycle Life, Self‐Healing Zinc–Iodine Flow Battery with High Power Density

Dithiolene Complexes of First‐Row Transition Metals for Symmetric Nonaqueous Redox Flow Batteries

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