Non-aqueous
redox flow batteries (RFBs) are promising energy storage devices owing
to the broad electrochemical window of organic solvents. Nonetheless,
the wide application of these batteries has been limited by the low
stability and limited solubility of organic materials, as well as
the insufficient ion conductivity of the cell separators in non-aqueous
electrolytes. In this study, two viologen analogues with poly(ethylene
glycol) (PEG) tails are designed as anolytes for non-aqueous RFBs.
The PEGylation of viologen not only enhances the solubility in acetonitrile
but also increases the overall molecular size for alleviated crossover.
In addition, a composite nanoporous aramid nanofiber separator, which
allows the permeation of supporting ions while inhibiting the crossover
of the designer viologens, is developed using a scalable doctor-blading
method. Paired with ferrocene, the full organic material-based RFB
presents excellent cyclability (500 cycles) with a retention capacity
per cycle of 99.93% and an average Coulombic efficiency of 99.3% at
a current density of 2.0 mA/cm2. The high performance of
the PEGylated viologen validates the potential of the PEGylation strategy
for enhanced organic material-based non-aqueous RFBs.
A non-aqueous redox flow battery based on all-PEGylated, metal-free compounds is presented. The PEGylation enhances the stability of the redox-active materials, alleviating crossover by increasing the anolyte and catholyte species’ molecular sizes.
The lack of a suitable ionic exchange membrane has retarded the development of organic nonaqueous redox flow batteries (RFBs). Membrane-free redox stratified batteries, wherein electroactive materials in immiscible nonaqueous and aqueous solvents as anolyte and catholyte, have emerged as a promising strategy to mitigate the high dependence of RFBs on battery separators. Here we report the exploration of the application of immiscible electrolytes, water and dichloromethane, in membrane-free redox stratified batteries. With 0.5 M phenothiazines in dichloromethane as the catholytes and zinc metal in aqueous electrolyte as the anolyte, the aqueous/ nonaqueous stratified battery presents stable long cycling with a capacity retention of 79.1% over 202 cycles under ambient testing conditions. Study of phenothiazines with varying lengths of alkyl chains (C0, C3, C8, and C18) reveals that the hydrophobicity of the phenothiazine molecules greatly affects the solubility in dichloromethane and battery cyclability. Computation on free energy of solvation and molecular dynamics is also performed to elucidate the hydrophobicity effects. The results presented in this work lay a solid foundation for potential development of the membrane-free RFBs.
The effects of primary and second coordination spheres on molecular electrocatalysis have been extensively studied, yet investigations of third functional spheres are rarely reported. Here, an electrocatalyst (ZnPEG8T) was developed with a hydrophilic channel as a third functional sphere that facilitates relay proton shuttling to the primary and second coordination spheres for enhanced catalytic CO2 reduction. Using foot‐of‐the‐wave analysis, the ZnPEG8T catalyst displayed CO2‐to‐CO activity (TOFmax) thirty times greater than that of the benchmark catalyst without a third functional sphere. A kinetic isotopic effect (KIE) study, in conjunction with voltammetry and UV/Vis spectroscopy, uncovered that the rate‐limiting step was not the protonation step of the metallocarboxylate intermediate, as observed in many other molecular CO2 reduction electrocatalysts, but rather the replenishment of protons in the proton‐shuttling channel. Controlled‐potential electrolysis using ZnPEG8T displayed a faradaic efficiency of 100 % for CO2‐to‐CO conversion at −2.4 V vs. Fc/Fc+. A Tafel plot was also generated for a comparison to other reported molecular catalysts. This report validates a strategy for incorporating higher functional spheres for enhanced catalytic efficiency in proton‐coupled electron‐transfer reactions.
The remediation of organohalides from water is a challenging process in environment protection and water treatment. Herein, we report a molecular copper(I) complex with two triazole units, CuT2, in a heterogeneous aqueous system that is capable of dechlorinating dichloromethane (CH 2 Cl 2 ) to afford hydrocarbons (methane, ethane, and ethylene). The catalytic performance is evaluated in water and presented high Faradaic efficiency (average 70% CH 4 ) across a range of potentials (−1.1 to −1.6 V vs Ag/AgCl) and high activity (maximum −25.1 mA/cm 2 at −1.6 V vs Ag/AgCl) with a turnover number of 2.0 × 10 7 . The CuT2 catalyst also showed excellent stability for 14 h of constant exposure to CH 2 Cl 2 and 10 h of CH 2 Cl 2 exposure cycling. The control compound, a copper-free triazole unit (T1), was also investigated under the same condition and showed inferior catalytic activity, indicating the importance of the copper center. Plausible catalytic mechanisms are proposed for the formation of C 1 and C 2 products via radical intermediates. Computational studies provided additional insight into the reaction mechanism and the selectivity toward the CH 4 formation. The findings in this study demonstrate that complex CuT2 is an efficient and stable catalyst for the dehalogenation of CH 2 Cl 2 and could potentially be used for the exploration of the removal of halogenated species from aqueous systems.
Redox‐flow batteries (RFBs) are a highly promising large‐scale energy storage technology for mitigating the intermittent nature of renewable energy sources. Here, the design and implementation of a micellization strategy in an anthraquinone‐based, pH‐neutral, nontoxic, and metal‐free aqueous RFB is reported. The micellization strategy (1) improves stability by protecting the redox‐active anthraquinone core with a hydrophilic poly(ethylene glycol) shell and (2) increases the overall size to mitigate the crossover issue through a physical blocking mechanism. Paired with a well‐established potassium ferrocyanide catholyte, the micelle‐based RFB displayed an excellent capacity retention of 90.7 % after 3600 charge/discharge cycles (28.3 days), corresponding to a capacity retention of 99.67 % per day and 99.998 % per cycle. The mechanistic studies of redox‐active materials were also conducted and indicated the absence of side reactions commonly observed in other anthraquinone‐based RFBs. The outstanding performance of the RFB demonstrates the effectiveness of the micellization strategy for enhancing the performance of organic material‐based aqueous RFBs.
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