Practical Approach to Large-Scale Electronic Structure Calculations in Electrolyte Solutions via Continuum-Embedded Linear-Scaling Density Functional Theory

Dziedzic, Jacek; Bhandari, Arihant; Anton, Lucian; Peng, Chao; Womack, James C.; Famili, Marjan; Kramer, Denis; Skylaris, Chris‐Kriton

doi:10.1021/acs.jpcc.0c00762

Cited by 21 publications

(35 citation statements)

References 53 publications

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“…However, they are fast to compute with and so are often used on larger-scale systems, such as pouch cells which are fabricated by stacking many single cells on top of each other, where the primary goal may be to investigate the thermal behaviour of the system, see for example [75,97], or to develop a battery management system. At the opposite end of the scale, density functional theory is applied to study battery physics on the atomistic scale, but the computational costs are so high that the simulation of even a single battery cell is out of reach of the most powerful modern computers, see [28]. The charge transport models discussed here provide a useful compromise between capturing meaningful physics, but nevertheless being cheap enough to use on problems of engineering relevance.…”

Section: Introductionmentioning

confidence: 99%

Charge transport modelling of Lithium-ion batteries

et al. 2021

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This paper presents the current state of mathematical modelling of the electrochemical behaviour of lithium-ion batteries (LIBs) as they are charged and discharged. It reviews the models developed by Newman and co-workers, both in the cases of dilute and moderately concentrated electrolytes and indicates the modelling assumptions required for their development. Particular attention is paid to the interface conditions imposed between the electrolyte and the active electrode material; necessary conditions are derived for one of these, the Butler–Volmer relation, in order to ensure physically realistic solutions. Insight into the origin of the differences between various models found in the literature is revealed by considering formulations obtained by using different measures of the electric potential. Materials commonly used for electrodes in LIBs are considered and the various mathematical models used to describe lithium transport in them discussed. The problem of upscaling from models of behaviour at the single electrode particle scale to the cell scale is addressed using homogenisation techniques resulting in the pseudo-2D model commonly used to describe charge transport and discharge behaviour in lithium-ion cells. Numerical solution to this model is discussed and illustrative results for a common device are computed.

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Section: Introductionmentioning

confidence: 99%

Charge transport modelling of Lithium-ion batteries

et al. 2021

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“…Inserting this ansatz into Poisson's equation [Equation ()] affords a model in which the dielectric interface is smooth, rather than sharp as it is in PCMs, yet one where the definition of the interface is updated self‐consistently as the density ρ ( r ) is iterated to convergence. The dependence of ε ( r ) on the density does mean that the Fock operator

δ scriptG / italicδρ

acquires an extra term relative to what was discussed in Section 2.1, namely 262

υ_{ε} ([], ρ) ((), r) = - \frac{1}{8 π} {‖\overset{false^}{bold∇} φ (boldr)‖}^{2} ((), \frac{δε [ρ]}{δρ (boldr)}) .

The SCCS model is increasingly being used in ab initio simulations of materials, for example, to model the aqueous electrolyte/solid‐state interfaces relevant in electrochemistry 28,82,264,268–274 . Some of that work points to limitations of the linear dielectric model itself (i.e., a breakdown of the assumption that P ∝ E ), which can result either from high field strength (“dielectric saturation”), 275,276 or else because the rotational response of the water molecules saturates at the electrode interface and consequently the susceptibility is smaller than it is in bulk water 271,272 .…”

Section: Methodsmentioning

confidence: 99%

“…These arise due to statistical correlations between ion positions that are neglected by the model in Equation (). It is therefore worth noting that for the small solutes that characterize most quantum chemistry applications, the effect of the mobile ions on

G_{elst}

is quite modest, 73,79 although there are effects on activity coefficients 73,82 . These effects are presumably magnified for a solute the size of a protein, but the intermediate size regime has hardly been explored.…”

Section: Continuum Electrostaticsmentioning

confidence: 99%

“…The SCCS model is increasingly being used in ab initio simulations of materials, for example, to model the aqueous electrolyte/solid-state interfaces relevant in electrochemistry. 28,82,264,[268][269][270][271][272][273][274] Some of that work points to limitations of the linear dielectric model itself (i.e., a breakdown of the assumption that P / E), which can result either from high field strength ("dielectric saturation"), 275,276 or else because the rotational response of the water molecules saturates at the electrode interface and consequently the susceptibility is smaller than it is in bulk water. 271,272 Limitations in the linearized Poisson-Boltzmann description of electrolyte effects have also been demonstrated.…”

Section: Cavitymentioning

confidence: 99%

“…675,677,686,687 Fundamentally, however, the interfacial solvation problem seems to cry out for a permittivity function ε(r) that assumes different values in different regions of space, that is, a method that solves the generalized Poisson equation with an anisotropic permittivity function, ε(r). Such a strategy has been pursued to describe the interface between a solid-state electrode and an aqueous electrolyte, 28,82,264,[268][269][270][271][272][273][274] as well as host/guest systems where the guest experiences a low-dielectric environment despite the fact that the host is dissolved in water. 688 Finally, anisotropic models have been used to compute VIEs of solutes at the air/water interface, 44,588 in order to connect with liquid microjet photoelectron spectroscopy.…”

Section: Anisotropic Solvationmentioning

confidence: 99%

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Dielectric continuum methods for quantum chemistry

Herbert

2021

WIREs Comput Mol Sci

141

195

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This review describes the theory and implementation of implicit solvation models based on continuum electrostatics. Within quantum chemistry this formalism is sometimes synonymous with the polarizable continuum model, a particular boundary‐element approach to the problem defined by the Poisson or Poisson–Boltzmann equation, but that moniker belies the diversity of available methods. This work reviews the current state‐of‐the art, with emphasis on theory and methods rather than applications. The basics of continuum electrostatics are described, including the nonequilibrium polarization response upon excitation or ionization of the solute. Nonelectrostatic interactions, which must be included in the model in order to obtain accurate solvation energies, are also described. Numerical techniques for implementing the equations are discussed, including linear‐scaling algorithms that can be used in classical or mixed quantum/classical biomolecular electrostatics calculations. Anisotropic models that can describe interfacial solvation are briefly described. This article is categorized under: Electronic Structure Theory > Ab Initio Electronic Structure Methods Molecular and Statistical Mechanics > Free Energy Methods

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