Discharge, Relaxation, and Charge Model for the Lithium Trivanadate Electrode: Reactions, Phase Change, and Transport

Abstract: The electrochemical behavior of lithium trivanadate (LiV 3 O 8 ) during lithiation, delithiation, and voltage recovery experiments is simulated using a crystal-scale model that accounts for solid-state diffusion, charge-transfer kinetics, and phase transformations. The kinetic expression for phase change was modeled using an approach inspired by the Avrami formulation for nucleation and growth. Numerical results indicate that the solid-state diffusion coefficient of lithium in LiV 3 O 8 is ∼10 −13 cm 2 s −1 an… Show more

“…Concentration variations within the solid-state are not neglected and are described by Equation 4, based on the crystal scale model developed by Brady et al 6 This equation describes the Fickian transport of lithium through the crystal and assumes that phase change proceeds through a chemical reaction. Equation 5 in Table I describes phase change: the process of lithium transferring between the α-and β-phases, is assumed not to be electrochemically driven, but chemically driven, where the term (c α -c α,sat ) is the driving force for phase change and k β is the kinetic rate constant.…”

“…The exponent m describes the dimensionality of phase growth (planar, cylindrical, spherical) and nucleation (instantaneous, progressive), and the exponent p describes the degree of self-passivation. It is assumed that the new phase grows planarly and self-passivation is proportional to the volume fraction 6 Electrode Scale Equations…”

“…The crystal scale model development is detailed by Brady et al 6 The most significant information is that the crystal is composed of three components: the α-phase, β-phase, and grain boundaries, whose volume fractions, θ i , sum to 1:…”

“…The crystal-scale parameters remain the same as those published by Brady et al 6 (D , but the phase change reaction rate constant, k β , was allowed to vary along with the solid-state electrical conductivity, σ, and electrolyte effective diffusion coefficient, D 0,ef f . These parameters were fit to the experimental data using 1000 Sobol points with the bounds:…”

“…1,4 Phase transitions during battery operation are significant because they have implications for electrochemical performance, rate capability, as well as cycle life. Previous studies have interrogated phase change using a variety of methods, both experimental and theoretical: electrochemical, [5][6][7] in-situ 8,9 and ex-situ 10 characterization (SEM, 7,11 XRD 4,5,7,10,11 ), DFT, 9,12 and continuum modeling. 6 Electrochemical measurements are commonly used to investigate battery performance.…”

Operando Study of LiV₃O₈Cathode: Coupling EDXRD Measurements to Simulations

“…Concentration variations within the solid-state are not neglected and are described by Equation 4, based on the crystal scale model developed by Brady et al 6 This equation describes the Fickian transport of lithium through the crystal and assumes that phase change proceeds through a chemical reaction. Equation 5 in Table I describes phase change: the process of lithium transferring between the α-and β-phases, is assumed not to be electrochemically driven, but chemically driven, where the term (c α -c α,sat ) is the driving force for phase change and k β is the kinetic rate constant.…”

“…The exponent m describes the dimensionality of phase growth (planar, cylindrical, spherical) and nucleation (instantaneous, progressive), and the exponent p describes the degree of self-passivation. It is assumed that the new phase grows planarly and self-passivation is proportional to the volume fraction 6 Electrode Scale Equations…”

“…The crystal scale model development is detailed by Brady et al 6 The most significant information is that the crystal is composed of three components: the α-phase, β-phase, and grain boundaries, whose volume fractions, θ i , sum to 1:…”

“…The crystal-scale parameters remain the same as those published by Brady et al 6 (D , but the phase change reaction rate constant, k β , was allowed to vary along with the solid-state electrical conductivity, σ, and electrolyte effective diffusion coefficient, D 0,ef f . These parameters were fit to the experimental data using 1000 Sobol points with the bounds:…”

“…1,4 Phase transitions during battery operation are significant because they have implications for electrochemical performance, rate capability, as well as cycle life. Previous studies have interrogated phase change using a variety of methods, both experimental and theoretical: electrochemical, [5][6][7] in-situ 8,9 and ex-situ 10 characterization (SEM, 7,11 XRD 4,5,7,10,11 ), DFT, 9,12 and continuum modeling. 6 Electrochemical measurements are commonly used to investigate battery performance.…”

Operando Study of LiV₃O₈Cathode: Coupling EDXRD Measurements to Simulations

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