An Fe<sup>III</sup> Azamacrocyclic Complex as a pH‐Tunable Catholyte and Anolyte for Redox‐Flow Battery Applications

Tsitovich, Pavel B.; Kosswattaarachchi, Anjula M.; Crawley, Matthew R.; Tittiris, Timothy Y.; Cook, Timothy R.; Morrow, Janet R.

doi:10.1002/chem.201704381

Cited by 29 publications

(37 citation statements)

References 37 publications

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“…The energy density is 8.4 mWh/L for the whole cell, which is too low for real-world applications, but is similar to that of other exploratory work that examined aqueous symmetric metal-ligand complexes, such as the 1 mM (aq) iron triazametallocycle-based RFB mentioned in the introduction, which has an energy density of 7.0 mWh/L. 27 Moreover, as shown in Figure S9, there was a negligible change in the colour of the membrane after 100 cycles. As seen in Figure 6a where ?…”

Section: Figure 1 (A)supporting

confidence: 68%

“…26 An elegant study of a triazametallocycle iron complex with pH-dependent oxidation states has demonstrated applicability as a posolyte at low pH, and a negolyte at high pH, and thus could serve as a symmetrical aqueous RFB, albeit with different pH values on opposite sides of the membrane. 27 In addition, a handful of examples of organic and polymerbased aqueous symmetric batteries have been tested, and include a combi-molecules comprising tethered negolyte-posolyte combinations of TEMPO and phenazine, 28 and TEMPO and viologen. 29 In this work we explore the properties and utility of a water soluble version of a bis(pyridine-2,6-diimine) cobalt(II) complex for aqueous symmetric RFB applications ( Figure 1).…”

Section: Introductionmentioning

confidence: 99%

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Aqueous Symmetrical Redox Flow Batteries Based Upon a pH-Responsive Cobalt Complex

Wang¹,

Sy²,

Zhou³

et al. 2019

Preprint

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<div>Aqueous symmetric redox flow batteries (RFB) are of great interest due to the non-flammability and high conductivity of the solvent, and avoidance of irreversible anolyte crossover seen in asymmetric cells. In this work, we introduce a simple octahedral Co(II) complex, termed BCPIP-Co(II), that has 4 appended carboxylic groups on the ligand periphery that render it both water-soluble and pH-sensitive in the range of pH 1.5 - 5.5. The complex has reversible BCPIP-Co(II-III) and BCPIP-Co(II-I) redox couples within the water splitting window, as well as fast kinetics. The overall charge of the complex varies from +3 to -3, resulting from the level of deprotonation of the carboxylic acid moieties and the oxidation state of the cobalt metal center, both of which affect the resulting redox properties. BCPIP-Co(II) was then incorporated, as both the posolyte and negolyte, into a symmetric aqueous RFB, demonstrating Coulombic efficiencies >99% for up to 100 cycles.</div>

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Section: Figure 1 (A)supporting

confidence: 68%

Section: Introductionmentioning

confidence: 99%

Aqueous Symmetrical Redox Flow Batteries Based Upon a pH-Responsive Cobalt Complex

Wang¹,

Sy²,

Zhou³

et al. 2019

Preprint

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“…This pH‐dependence is due to the proton‐coupled electron‐transfer (PCET) involved in the redox chemistry of MB. Active species that invoke PCET redox chemistry have been previously observed in a handful of other molecules, the most notable being quinones ,. This pH tunability can serve as the basis for enhancing cell voltages by shifting the E 1/2 values .…”

Section: Resultsmentioning

confidence: 86%

Repurposing the Industrial Dye Methylene Blue as an Active Component for Redox Flow Batteries

Kosswattaarachchi

Cook

2018

ChemElectroChem

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Methylene blue is a common component of industrial wastewater in the textile industry. The redox properties of this environmentally damaging molecule make it suitable for use in the electrolyte solutions of aqueous redox flow batteries. Here, we carry out electrochemical analyses of aqueous methylene blue solutions to establish the dye as a pH tuneable, two‐electron redox transfer agent with fast transfer kinetics. Galvanostatic charge‐discharge experiments demonstrated ∼100 % coulombic efficiency for 50 cycles over seven days. Cycling performance was dependent on the membrane separator used. Cells containing an AMI‐7001 membrane showed a capacity decay with the state‐of‐charge falling to 56 % due to dye adsorption. Nafion NE1035 showed no adsorption nor membrane crossover. The combination of chemical and redox stability, and fast kinetics motivate the recycling of methylene blue wastewater as the basis for flow battery electrolyte solutions.

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“…The total charge of the Ru complex is omitted. of using a PCET system in this way had been implemented with organic quinone derivatives, [52] but its scope was extended to redox-flow batteries by using a pHtunable Fe(III) azamacrocyclic complex as both the catholyte and anolyte based on the multiple protonated forms of the Fe complex [53].…”

Section: Figure 11mentioning

confidence: 99%

Surface-Confined Ruthenium Complexes Bearing Benzimidazole Derivatives: Toward Functional Devices

Haga¹

2022

Ruthenium - An Element Loved by Researchers

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Substitutionally inert ruthenium complexes bearing benzimidazole derivatives have unique electrochemical and photochemical properties. In particular, proton coupled electron transfer (PCET) in ruthenium–benzimidazole complexes leads to rich redox chemistry, which allows e.g. the tuning of redox potentials or switching by deprotonation. Using the background knowledge from acquired from their solution-state chemistry, Ru complexes immobilized on electrode surfaces have been developed and these offer new research directions toward functional molecular devices. The integration of surface-immobilized redox-active Ru complexes with multilayer assemblies via the layer-by-layer (LbL) metal coordination method on ITO electrodes provides new types of functionality. To control the molecular orientation of the complexes on the ITO surface, free-standing tetrapodal phosphonic acid anchor groups were incorporated into tridentate 2,6-bis(benzimidazole-2-yl)pyridine or benzene ligands. The use of the LbL layer growth method also enables “coordination programming” to fabricate multilayered films, as a variety of Ru complexes with different redox potentials and pKa values are available for incorporation into homo- and heterolayer films. Based on this strategy, many functional devices, such as scalable redox capacitors for energy storage, photo-responsive memory devices, proton rocking-chair-type redox capacitors, and protonic memristor devices have been successfully fabricated. Further applications of anchored Ru complexes in photoredox catalysis and dye-sensitized solar cells may be possible. Therefore, surface-confined Ru complexes exhibit great potential to contribute to the development of advanced functional molecular devices.

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An Fe^III Azamacrocyclic Complex as a pH‐Tunable Catholyte and Anolyte for Redox‐Flow Battery Applications

Cited by 29 publications

References 37 publications

Aqueous Symmetrical Redox Flow Batteries Based Upon a pH-Responsive Cobalt Complex

Aqueous Symmetrical Redox Flow Batteries Based Upon a pH-Responsive Cobalt Complex

Repurposing the Industrial Dye Methylene Blue as an Active Component for Redox Flow Batteries

Surface-Confined Ruthenium Complexes Bearing Benzimidazole Derivatives: Toward Functional Devices

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An FeIII Azamacrocyclic Complex as a pH‐Tunable Catholyte and Anolyte for Redox‐Flow Battery Applications

Cited by 29 publications

References 37 publications

Aqueous Symmetrical Redox Flow Batteries Based Upon a pH-Responsive Cobalt Complex

Aqueous Symmetrical Redox Flow Batteries Based Upon a pH-Responsive Cobalt Complex

Repurposing the Industrial Dye Methylene Blue as an Active Component for Redox Flow Batteries

Surface-Confined Ruthenium Complexes Bearing Benzimidazole Derivatives: Toward Functional Devices

Contact Info

Product

Resources

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An Fe^III Azamacrocyclic Complex as a pH‐Tunable Catholyte and Anolyte for Redox‐Flow Battery Applications