Interfacial ion solvation: Obtaining the thermodynamic limit from molecular simulations

Cox, Stephen J.; Geissler, Phillip L.

doi:10.1063/1.5020563

Cited by 25 publications

(45 citation statements)

References 124 publications

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“…Both cases are shown in Figure 2b, which shows that inclusion of distant boundaries, both Bethe and physical boundaries, oppose the usual charge hydration asymmetry in the case of SPC/E-like water models because both ∆v q C and (∆v q C + ∆v q D ) are negative. This is in agreement with recent results from Cox and Geissler, who computed ionic charging free energies in systems with and without an explicit water-vapor interface, and showed that proper inclusion of the boundary potentials, as well as important system size and geometry-dependent dielectric response corrections, bring the two sets of free energies into agreement 57 .…”

Section: Implications For Ions With Excluded Volume Coressupporting

confidence: 92%

“…Periodic boundaries result in an ionic charging free energy that arises purely from local structural perturbations, both charging induced, ∆G c IS , and from any local core contributions to ρ q 0 (r) that may contribute to ∆G c PB . Note that PBCs may lead to additional finite size effects on ∆G c IS that have been discussed throughout the literature 50,53,56,57 , and we ignore these well understood corrections.…”

Section: A Site-based Periodic Boundariesmentioning

confidence: 99%

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The Influence of Distant Boundaries on the Solvation of Charged Particles

Remsing

Weeks

2019

J Stat Phys

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The long-ranged nature of the Coulomb potential requires a proper accounting for the influence of even distant electrostatic boundaries in the determination of the solvation free energy of a charged solute. We introduce an exact rewriting of the free energy change upon charging a solute that explicitly isolates the contribution from these boundaries and quantifies the impact of the different boundaries on the free energy. We demonstrate the importance and advantages of appropriately referencing the electrostatic potential to that of the vacuum through the study of several simple model charge distributions, for which we can isolate an analytic contribution from the boundaries that can be readily evaluated in computer simulations of molecular systems. Finally, we highlight that the constant potential of the bulk dielectric phase -the Bethe potential -cannot contribute to the solvation thermodynamics of a single charged solute when the charge distributions of the solvent and solute do not overlap in relevant configurations. But when the charge distribution of a single solute can overlap with the intramolecular charge distribution of solvent molecules, as is the case in electron holography, for example, the Bethe potential is needed when comparing to experiment. Our work may also provide insight into the validity of "extra thermodynamic assumptions" traditionally made during the experimental determination of single ion solvation free energies.

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Section: Implications For Ions With Excluded Volume Coressupporting

confidence: 92%

Section: A Site-based Periodic Boundariesmentioning

confidence: 99%

The Influence of Distant Boundaries on the Solvation of Charged Particles

Remsing

Weeks

2019

J Stat Phys

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“…Even so, Cox and Geissler have shown that dielectric continuum descriptions can provide highly accurate finite size corrections for ion solvation at planar interfaces. 57 Together these results make clear that the key is to unravel the local and non-linear electrostatic effects through explicit atomistic or variable density representations, that is then embedded in or corrected by a continuum model for the long-range electrostatic effects. This is likely why modified Poisson Boltzmann treatments/DFT 58 and classical/quantum DFT approaches 56 and recent hybrid and double hybrid functionals which incorporate some percentage of exact exchange, are addressing better QM accuracy 61 , and new approaches have been introduced that incorporate true many-body polarization effects across the QM/MM boundary.…”

Section: Summary and Future Directionsmentioning

confidence: 91%

Computational optimization of electric fields for better catalysis design

2018

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Although the ubiquitous role that long-ranged electric fields play in catalysis has been recognized, it is seldom used as a primary design parameter in the discovery of new catalytic materials. Here we illustrate how electric fields have been used to computationally optimize biocatalytic performance of a synthetic enzyme, and how they could be used as a unifying descriptor for catalytic design across a range of homogeneous and heterogeneous catalysts. While focusing on electrostatic environmental effects may open new routes toward the rational optimization of efficient catalysts, much more predictive capacity is required of theoretical methods to have a transformative impact in their computational design-and thus experimental relevance-when using electric field alignments in the reactive centres of complex catalytic systems.

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“…Contrary to Born's result, computer simulations indicate that the sign of the charge of small ions can signicantly inuence their charging free energy F chg (q, R), i.e., the work involved in reversibly introducing the solute's charge q. [30][31][32][33][34][35][36][37][38][39] This dependence is most easily scrutinized for simple point charge (SPC) models of molecular interactions, where an ion's charge can be varied independently of its other properties. In SPC/E water, 40 for instance, charging a solute roughly the size of uoride (R F z 0.317 nm) has an asymmetry, F chg (e, R F ) À F chg (Àe, R F ) z 16 kcal mol À1 , almost 30 times larger than thermal energy k B T. Here, e is the magnitude of an electron's charge.…”

Section: Distant Interfaces and The Neutral Cavity Potentialmentioning

confidence: 87%