High-Voltage Aqueous Redox Flow Batteries Enabled by Catalyzed Water Dissociation and Acid–Base Neutralization in Bipolar Membranes

Yan, Zi; Wycisk, Ryszard; Metlay, Amy S.; Xiao, Langqiu; Yoon, Yein; Pintauro, Peter N.; Mallouk, Thomas E.

doi:10.1021/acscentsci.1c00217

Cited by 41 publications

(68 citation statements)

References 40 publications

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“…53 Alternatively, we experimentally observed a dramatic increase in the acid− base neutralization rate in the BPM by modifying the interface with a graphite oxide (GO) catalyst. 51 This effect was confirmed by comparing the experimental data to numerical models, in which the observed potential−current density curves could be fully reproduced only if both the water dissociation and acid−base neutralization reactions were enhanced by interfacial catalysts (Figure 6b). Understanding the mechanism at the microscopic level would further inform the design of BPMs under forward bias.…”

Section: ■ Polarization Losses In Buffer-based Electrolyzers and In R...mentioning

confidence: 64%

“…Comparison of the experimental cross-membrane potential vs current density of BPMs with and without interfacial catalysts under reverse and forward bias (lower right) . Reproduced with permission from ref . Copyright 2021 American Chemistry Society.…”

Section: Bpm-based Fuel Cells and Redox Flow Batteriesmentioning

confidence: 86%

“…For example, the formal potential of sulfonated propylviologen (SPV) (∼0.58 V, vs Ag/AgCl) is unaffected by the electrolyte pH between pH 0 and 14 (0 mV/pH slope). Coupling SPV in an acid with ferrocyanide in a base, with the two electrolytes separated by a BPM, leads to a redox flow battery with an open circuit voltage (OCV) of ∼1.6 V, an increase of ∼0.7 V compared to the same cell operating with both molecules under alkaline conditions (Figure b) . The Pourbaix diagram of 1,7-disulfonate anthraquinone (DSAQ), on the other hand, shows slopes of −59, −29, and ∼0 mV/pH within the pH ranges of 0–7, 7–10, and 10–14, resulting in an OCV increase of ∼350 mV, close to the theoretical value (59 mV/pH × 4 pH units = 236 mV for pH 10–14, plus 29 mV/pH × 3 pH units = 87 mV for pH 7–10).…”

Section: Bpm-based Fuel Cells and Redox Flow Batteriesmentioning

confidence: 99%

“…The acid–base configuration gave a higher open circuit potential (dashed lines), even though both used the same redox molecules, SPV and ferrocyanide (lower left). Comparison of the experimental cross-membrane potential vs current density of BPMs with and without interfacial catalysts under reverse and forward bias (lower right) . Reproduced with permission from ref .…”

Section: Bpm-based Fuel Cells and Redox Flow Batteriesmentioning

confidence: 99%

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Bipolar Membranes for Ion Management in (Photo)Electrochemical Energy Conversion

Yan

2021

Acc. Mater. Res.

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Conspectus (Photo)electrochemical energy conversion is important in the development of a carbon-neutral energy economy because it can provide a pathway for mitigating the intermittency of renewable energy sources such as wind and solar. In order to operate efficiently, these technologies, which include photoelectrochemical cells, water and CO2 electrolyzers, fuel cells, and redox flow batteries, require fast charge transfer kinetics at the electrode/electrolyte interface as well as robust ion management in the electrolyte. In conventional electrolyzers and fuel cells, the electrolyte is strongly acidic or basic and ionic current is carried by H+ or OH– ions. In contrast, photoelectrodes and electrocatalysts for water splitting are often studied in buffered solutions. The question of ion balance in these systems led us to analyze the polarization losses due to ion concentration gradients in cells that employed various buffer–membrane combinations. Continuously driving the buffer ions across an ionomer membrane not only lowers the buffer capacity of an aqueous electrolyte but also introduces pH gradients that result in significant energy losses. To address the problem, we and other groups have studied the use of reverse-biased bipolar membranes (BPMs) in (photo)electrolytic cells. BPMs consist of an anion exchange layer (AEL) laminated with a cation exchange layer (CEL) and are usually equipped with a catalytic layer in between to accelerate the water dissociation reaction. At the AEL/CEL interface, water dissociates into protons and hydroxide ions, which replenish those consumed at the cathode and anode. Compared to conventional water electrolyzers with proton/anion exchange membranes (PEM/AEM), BPM electrolyzers provide the unique advantage of continuously operating the cathode and anode under different pH conditions, which is desirable when the two electrode reactions have different pH requirements. BPMs also enable the use of buffered electrolytes at pH values that are optimized for electrode stability and product selectivity in applications such as CO2 electrolysis. Product crossover losses and CO2 pumping can be dramatically reduced in BPM-based CO2 electrolyzers, relative to conventional alkaline membranes, by electrostatic repulsion (of anionic products) and electroosmotic drag (for neutral products). BPM-based gas fed CO2 electrolyzers can achieve high current density, but they suffer from low Faradaic efficiency (FE) due to the acidic local environment of the CEL. This problem can be mitigated by adding an aqueous buffering layer or by creating a weak acid cation exchange film on the CEL face of the membrane. The use of BPMs in fuel cells and redox flow batteries offers some interesting advantages. Configurations with both reverse and forward bias have been studied, but forward bias has been favored due to material compatibility, reaction kinetics, and thermodynamic considerations. The net reaction at the AEL/CEL interface is the acid–base neutralization reaction, which has a high inherent reaction rate...

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Section: ■ Polarization Losses In Buffer-based Electrolyzers and In R...mentioning

confidence: 64%

Section: Bpm-based Fuel Cells and Redox Flow Batteriesmentioning

confidence: 86%

Section: Bpm-based Fuel Cells and Redox Flow Batteriesmentioning

confidence: 99%

Section: Bpm-based Fuel Cells and Redox Flow Batteriesmentioning

confidence: 99%

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Bipolar Membranes for Ion Management in (Photo)Electrochemical Energy Conversion

Yan

2021

Acc. Mater. Res.

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“…1a ). BPMs were first conceived as an ionic counterpart to current-rectifying semiconductor pn junctions 3 – 5 , and now are used in electrodialysis devices for desalination and acid/base production from brine 6 , fuel cells 7 , water and CO 2 electrolysis 8 , 9 , flow batteries 10 , and protonic diodes 11 . They provide distinct alkaline and acidic environments that are ideal for water oxidation and water reduction, respectively, offering new pathways for increasing electrolyzer performance while reducing or eliminating precious metals use 12 .…”

Section: Introductionmentioning

confidence: 99%

Design principles for water dissociation catalysts in high-performance bipolar membranes

et al. 2022

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Water dissociation (WD, H2O → H+ + OH−) is the core process in bipolar membranes (BPMs) that limits energy efficiency. Both electric-field and catalytic effects have been invoked to describe WD, but the interplay of the two and the underlying design principles for WD catalysts remain unclear. Using precise layers of metal-oxide nanoparticles, membrane-electrolyzer platforms, materials characterization, and impedance analysis, we illustrate the role of electronic conductivity in modulating the performance of WD catalysts in the BPM junction through screening and focusing the interfacial electric field and thus electrochemical potential gradients. In contrast, the ionic conductivity of the same layer is not a significant factor in limiting performance. BPM water electrolyzers, optimized via these findings, use ~30-nm-diameter anatase TiO2 as an earth-abundant WD catalyst, and generate O2 and H2 at 500 mA cm−2 with a record-low total cell voltage below 2 V. These advanced BPMs might accelerate deployment of new electrodialysis, carbon-capture, and carbon-utilization technology.

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N, B codoped graphite felt for high‐performance 1,8‐dihydroxyanthraquinone redox flow battery

Deng¹,

Cai

Huang

2022

Energy Storage

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In this article, a graphite felt electrode was modified by NS double‐element and NB double‐element codoping. The surface morphology, crystal structure, element content, and surface chemical state of the modified electrode were characterized by scanning electron microscopy, X‐ray powder diffraction (XRD), Raman spectroscopy, and X‐ray photoelectron spectroscopy. The electrochemical performance of the modified electrode was evaluated by cyclic voltammetry, electrochemical impedance spectra, and a single cell. The results show that nitrogen (N) and boron (B) double‐element codoping can enhance the catalytic activity of graphite felt and create abundant defect sites, which increases the electrocatalytic activity by approximately a factor of 2. The reason why the doped graphite felt can obtain higher electrocatalytic activity may be related to the synergy between N and B atoms, especially the synergy between pyridine‐N and BC3, and the resistance of the first charge transfer reaction of 1,8‐dihydroxyanthraquinone on the doped graphite felt electrode is then reduced.

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High-Voltage Aqueous Redox Flow Batteries Enabled by Catalyzed Water Dissociation and Acid–Base Neutralization in Bipolar Membranes

Cited by 41 publications

References 40 publications

Bipolar Membranes for Ion Management in (Photo)Electrochemical Energy Conversion

Bipolar Membranes for Ion Management in (Photo)Electrochemical Energy Conversion

Design principles for water dissociation catalysts in high-performance bipolar membranes

N, B codoped graphite felt for high‐performance 1,8‐dihydroxyanthraquinone redox flow battery

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