Complexes Containing Redox Noninnocent Ligands for Symmetric, Multielectron Transfer Nonaqueous Redox Flow Batteries

Cabrera, Pablo J.; Yang, Xuelin; Suttil, James A.; Hawthorne, Krista L.; Brooner, Rachel E. M.; Sanford, Melanie S.; Thompson, Levi T.

doi:10.1021/acs.jpcc.5b03582

Cited by 79 publications

(84 citation statements)

References 44 publications

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“…Metal coordination complexes, in particular, have been a focal point for redox carrier development with those using the tris acetylacetonate ligand set thoroughly studied for V, Cr, and Mn variations, along with extensive ligand modification . Non‐innocent ligands have been prominently targeted of late, with examinations of bipyridine complexes, modified versions, and three‐coordinate hybrids . Recently, polyoxometalate complexes have been revised for nonaqueous systems, exhibiting excellent reversibility albeit with a relatively small potential …”

Section: Figurementioning

confidence: 99%

Linked Picolinamide Nickel Complexes as Redox Carriers for Nonaqueous Flow Batteries

et al. 2019

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The use of nickel complexes utilizing non-innocent ligands based on picolinamide to functiona sr edox carriers in flow batteries was explored. The picolinamidem oiety was linked together with ÀCH 2 CH 2 À (bpen), ÀCH 2 CH 2 CH 2 À (bppn), and ÀC 6 H 4 À (bpb) moieties, resulting in two, three, and four quasireversible waves, respectively,f or the nickel complexes and > 3V differenceb etween the outermost positivea nd negative waves. Ther edox events were theoretically modelled for each complex, showinge xcellent agreement (< 0.3 Vd ifference)b etween the experimental and modelled potentials. Bulk cycling of the most soluble complex, Ni(bppn), indicated only one of the three waves was reversible. Therefore, Ni(bppn) has the ability to act as an egative charge redox carrier in flow cells.Although lithium ion batteries tend to dominate the headlines, grid-scale energy storagew ill be served by av ariety of technologies depending on the time period of service. [1] For several decades, one technology attractive for > 4h of discharge is the redox flow battery (RFB, Figure 1). In contrastt os econdary batteries, in which the energy is stored within stationarye lectrodes, RFBs store and release energy from ar edox reaction between soluble chemical species, called redox carriers. At ypical non-hybrid RFB design has two storage tanks for the redox carriers that can be scaled independently of the cell, thereby imparting greater flexibility than as econdary battery,i nw hich power and energy are coupled( Figure1). Aqueousv anadium RFBs are the most developed technology availabley et suffer from the high cost of precursors (vanadium) and low stored energy density.D emand for improvements in energy storage has seen RFB research explode with significant advances: [2] greatly improved vanadium RFBc apacities, [3] identification of

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Section: Figurementioning

confidence: 99%

Linked Picolinamide Nickel Complexes as Redox Carriers for Nonaqueous Flow Batteries

et al. 2019

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“…[3][4][5] As energy is stored externally to the electrochemical reactor,t he capacity can be increased independently of the battery power.A tp resent,c ommercial RFBs utilize aqueous electrolyte solutions of inorganic metal salts, however, despite continualp rogress in powero utputs and efficiencies being made, the cell potentiali si nherently limitedb y the narrow (1.23 V) electrochemical window of water.I nstead, the developmento fn onaqueous RFBs, which use organic solvents with wide electrochemical windows,i sa nticipated to improve the voltage outputs. [12][13][14][15] Indeed, several metal coordination complexes have been tested as electrolytes for nonaqueous RFBs with cell potentials in excess of 1.23 V; these contain acetylacetonate, [12,[16][17][18][19][20][21] bipyridine, [13,15,[22][23][24][25] phenanthroline, [26,27] terpyridine-like, [14,15] trimetaphosphate, [28] and macrocyclic [29,30] ligands. [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.…”

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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“…Cycling solutions of metal acetylacetonates in acetonitrile reveals significant capacity fade that is often attributed to irreversible ligand shedding and/or irreversible oxidation reactions . Chromium(III) bipyridine complexes have six redox couples over a 2 V window and solubilities approaching 1 m . The multielectron transfer capabilities have been linked to non‐innocence (redox activity) of the bipyridine ligands.…”

Section: Introductionmentioning

confidence: 99%

“…The multielectron transfer capabilities have been linked to non‐innocence (redox activity) of the bipyridine ligands. When cycled in an H‐cell, however, solutions of Cr(bpy) 3 in acetonitrile reach less than 30 % of their theoretical capacities, and significant capacity fade occurs . Wei et al.…”

Section: Introductionmentioning

confidence: 99%

“…[26] Cycling solutions of metal acetylacetonates in acetonitrile reveals significant capacity fade that is often attributed to irreversible ligand sheddinga nd/or irreversible oxidation reactions. [17-19, 21, 26] Chromium(III) bipyridine complexes have six redox couples over a2Vw indow and solubilitiesa pproaching 1 m. [10] The multielectron transfer capabilitiesh ave been linked to non-innocence (redox activity) of the bipyridine ligands. When cycled in an H-cell,h owever, solutionso f Cr(bpy) 3 in acetonitriler each less than 30 %o ft heir theoretical capacities, and significant capacity fade occurs.…”

Section: Introductionmentioning

confidence: 99%

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Characterization of Structural and Electronic Transitions During Reduction and Oxidation of Ru(acac)₃ Flow Battery Electrolytes by using X‐ray Absorption Spectroscopy

et al. 2016

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Metal acetylacetonates possess several very attractive electrochemical properties; however, their cyclabilities fall short of targets for use in nonaqueous redox flow batteries. This paper describes structural and compositional changes during the reduction and oxidation of ruthenium(III) acetylacetonate [Ru(acac)3], a representative acetylacetonate. Voltammetry, bulk electrolysis, and in situ X‐ray absorption spectroscopy (XAS) results are complemented by those from density functional theory (DFT) calculations. The reduction of Ru(acac)3 in acetonitrile is highly reversible, producing a couple at −1.1 V versus Ag/Ag+. In situ XAS and DFT indicate the formation of [Ru(acac)3]− with Ru−O bonds lengthened relative to Ru(acac)3, nearly all of the charge localized on Ru, and no ligand shedding. The oxidation of Ru(acac)3 is quasireversible, with a couple at 0.7 V. The initial product is likely [Ru(acac)3]+; however, this species is short‐lived, converting to a product with a couple at −0.2 V, a structure that is nearly identical to that of Ru(acac)3 within 3 Å of Ru, and approximately 70 % of the charge extracted from Ru (balance from acetylacetone). This non‐innocence likely contributes to the instability of [Ru(acac)3]+. Taken together, the results suggest that the stabilities and cyclabilities of acetylacetonates are determined by the degree of charge transfer to/from the metal.

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Complexes Containing Redox Noninnocent Ligands for Symmetric, Multielectron Transfer Nonaqueous Redox Flow Batteries

Cited by 79 publications

References 44 publications

Linked Picolinamide Nickel Complexes as Redox Carriers for Nonaqueous Flow Batteries

Linked Picolinamide Nickel Complexes as Redox Carriers for Nonaqueous Flow Batteries

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

Characterization of Structural and Electronic Transitions During Reduction and Oxidation of Ru(acac)₃ Flow Battery Electrolytes by using X‐ray Absorption Spectroscopy

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Complexes Containing Redox Noninnocent Ligands for Symmetric, Multielectron Transfer Nonaqueous Redox Flow Batteries

Cited by 79 publications

References 44 publications

Linked Picolinamide Nickel Complexes as Redox Carriers for Nonaqueous Flow Batteries

Linked Picolinamide Nickel Complexes as Redox Carriers for Nonaqueous Flow Batteries

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

Characterization of Structural and Electronic Transitions During Reduction and Oxidation of Ru(acac)3 Flow Battery Electrolytes by using X‐ray Absorption Spectroscopy

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Characterization of Structural and Electronic Transitions During Reduction and Oxidation of Ru(acac)₃ Flow Battery Electrolytes by using X‐ray Absorption Spectroscopy