Molecular Simulations of Aqueous Electrolytes: Role of Explicit Inclusion of Charge Transfer into Force Fields

Berkowitz, Max L.

doi:10.1021/acs.jpcb.1c08383

Cited by 7 publications

(9 citation statements)

References 51 publications

(103 reference statements)

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“…20 Classical forcefields were shown to lead to a retardation of water dynamics for all investigated cations, including Cs + , [19][20][21] which therefore contrasts with the acceleration that has been measured by several techniques for this dilute cation. This has led to the suggestion that DFT-based MD 21 or simulations accounting for charge transfer 22 are required. However, another promising approach relies on scaled ion charges, 23,24 that implicitly account for the fast electronic dielectric response of water.…”

Section: Simulation Strategy and Modelsmentioning

confidence: 99%

“…We use molecular dynamics simulations which have already been successfully employed to elucidate how anions affect water reorientation dynamics. 7,8,14,15 However, for cations, traditional classical forcefields have been shown to fail to reproduce the experimentally observed acceleration of water dynamics induced by some large cations, [19][20][21] and it has been suggested that density functional theory(DFT)-based simulations 21 or simula-tions explicitly accounting for cation-water charge transfer 22 are required. Here we performed both DFT-based simulations and classical non-polarizable simulations with a rescaled-cation charge (ECC) approach.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

On water reorientation dynamics in cation hydration shells

Pluhařová

Stirnemann

Laage

2022

Journal of Molecular Liquids

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Section: Simulation Strategy and Modelsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

On water reorientation dynamics in cation hydration shells

Pluhařová

Stirnemann

Laage

2022

Journal of Molecular Liquids

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“…126 Further reparameterization of polarizable FFs to improve agreement presents a major challenge as the slow dynamics of DESs necessitates in impractically long time lengths to achieve statistically accurate results. 124 New methods or approaches, perhaps encompassing machine learning or FFs with explicit inclusion of charge transfer, 149,150 will be required to achieve accurate self-diffusivity reproduction and prediction for DESs. As one considers the potential for dramatic computational advances over the next 25 years, it is not difficult to imagine a day when FFs could be completely replaced with low-cost QM methods, particularly for solvent systems such as DESs.…”

Section: Self-diffusion Coefficientsmentioning

confidence: 99%

Simulation of deep eutectic solvents: Progress to promises

Velez

Acevedo

2022

WIREs Comput Mol Sci

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Deep eutectic solvents (DESs) are binary or ternary mixtures of compounds that possess significant melting point depressions relative to the pure isolated components. The discovery of DESs has been a major breakthrough with multiple fields benefitting from their low cost and tunable physiochemical properties. However, tailoring DESs for specific applications through their practically unlimited synthetic combinations can be as much a hindrance as a benefit given the expense and time-required to perform large-scale experimental measurements. This emphasizes the need for fast computational tools capable of making accurate predictions of DES physiochemical properties exclusively from molecular structure. Yet, these systems are not trivial to model or simulate at the atomic level given their exceedingly nonideal behaviors, asymmetry of components, and the complexity of their molecular electrostatic interactions. Despite the challenge, computational reports featuring quantum mechanical (QM) methods have provided significant understanding into the relationship between the melting point depression and the unique and complex hydrogen bond network present in DESs. Classical molecular dynamics (MD) methods have examined bulk-phase solvent organization in conjunction with thermodynamic and transport properties. Machine learning (ML) algorithms have shown great potential as structure-property prediction tools. Overall, this review highlights computational accomplishments that have meaningfully advanced our understanding of DESs and strives to give the reader a sense of the overall strengths and drawbacks of the methodologies employed while hinting at promises of advances to come.

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“…We note that considering the charged system without a counter ion implicitly assumes a model for a diluted solution/interface. From prior work with charged species in the literature such an approach is warranted if one takes into account the effects of the polarization of the solvent 86,[89][90][91][92][93][94] , and has been shown to yield spectroscopic results 62,95 that closely match experimental measurements, provided of course the model mirrors the essential features of the experimental system.…”

Section: B Md-derived Structuresmentioning

confidence: 99%