2017
DOI: 10.1149/2.0201711jes
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Quantifying Mass Transfer Rates in Redox Flow Batteries

Abstract: Engineering the electrochemical reactor of a redox flow battery (RFB) is critical to delivering sufficiently high power densities, as to achieve cost-effective, grid-scale energy storage. Cell-level resistive losses reduce RFB power density and originate from ohmic, kinetic, or mass transfer limitations. Mass transfer losses affect all RFBs and are controlled by the active species concentration, state-of-charge, electrode morphology, flow rate, electrolyte properties, and flow field design. The relationship am… Show more

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Cited by 151 publications
(204 citation statements)
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“…7,8,27 AqRFB development has recently benefited from a series of studies implementing a single electrolyte diagnostic flow cell technique 31 to systematically evaluate cell designs 32 and to better elucidate cell-level performance limitations relating to ohmic, charge transfer, and mass transfer losses. 27,[33][34][35] A schematic of this single electrolyte technique is provided in Figure 1a, where a flow cell is connected to a single electrolyte reservoir at 50% state-of-charge (SOC). The electrolyte passes through the positive side of the cell, where the active species are oxidized, and then loops back through the negative side of the cell, where the charged species are reduced.…”
mentioning
confidence: 99%
“…7,8,27 AqRFB development has recently benefited from a series of studies implementing a single electrolyte diagnostic flow cell technique 31 to systematically evaluate cell designs 32 and to better elucidate cell-level performance limitations relating to ohmic, charge transfer, and mass transfer losses. 27,[33][34][35] A schematic of this single electrolyte technique is provided in Figure 1a, where a flow cell is connected to a single electrolyte reservoir at 50% state-of-charge (SOC). The electrolyte passes through the positive side of the cell, where the active species are oxidized, and then loops back through the negative side of the cell, where the charged species are reduced.…”
mentioning
confidence: 99%
“…Importantly, this steady-state model assumes that variations in active species concentration in an electrode are negligible in the directions parallel to the separator, which holds true when the electrolyte flow rate is very high relative the rate of change in battery SOC (i.e., low reactant conversion per pass). 82 This assumption aligns with high power RFB cell design, where typically the mass transfer increases afforded by pumping the electrolyte faster lead to improvements in power density that vastly outweigh the pumping losses associated with the faster flowing electrolyte. 46 To briefly summarize the full derivation and analysis available in Ref.…”
Section: Computing Cell Area Specific Resistancementioning
confidence: 78%
“…80 R DC = 2(R contact + R electrode ) + R mem [7] Electrode resistance model.-The electrode resistance contribution to R DC is computed using a one-dimensional, steady-state porous electrode polarization model from a recent publication, and this model was validated with experimental flow cell polarization data employing various flow fields and electrolyte flow rates. 82 The model calculates individual electrode polarization, accounting for overpotential losses due to the convective mass transfer, Butler-Volmer reaction kinetics, and the electrolyte resistivity in the pore-phase of the porous electrode. Importantly, this steady-state model assumes that variations in active species concentration in an electrode are negligible in the directions parallel to the separator, which holds true when the electrolyte flow rate is very high relative the rate of change in battery SOC (i.e., low reactant conversion per pass).…”
Section: Computing Cell Area Specific Resistancementioning
confidence: 99%
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“…Galvanostatic battery experiments were performed by using ac onventional zero-gap flow-cell manufactured in house;t he "Gen 2 flow-cell" was reproduced from ar eported method [47,48] (see the Supporting Information for further details). Experiments were conducted by using af low-through flow field (FTFF), 1mmc arbon paper electrodes (Technical Fibre Products Ltd.,p olyvinyl alcohol binder,2 .08 cm 2 active area) and either aC elgard membrane (Celgard 2500 Microporous Membrane, 25 mmt hickness) or F-930 cation exchange membrane (fumapem F-930, FuMA-Tech GmbH, 30 mmt hickness).…”
Section: Flow Batterycharge-dischargee Xperimentsmentioning
confidence: 99%