Transferable Ion Force Fields in Water from a Simultaneous Optimization of Ion Solvation and Ion–Ion Interaction

Loche, Philip; Steinbrunner, P.; Friedowitz, Sean; Netz, Roland R.; Bonthuis, Douwe Jan

doi:10.1021/acs.jpcb.1c05303

Cited by 49 publications

(58 citation statements)

References 56 publications

(141 reference statements)

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“…4-site water models (TIP4P-D, followed by TIP4P-Ew, and TIP4P/2005) lead to larger deviations despite the fact that OPC is also a 4-site model (Table S4). This result has not been expected based on previous work which showed reasonable transferability of ion parameters within water models of the same complexity 1,2,67 .…”

Section: Resultscontrasting

confidence: 84%

Magnesium Force Fields for OPC Water with Accurate Solvation, Ion-Binding, and Water-Exchange Properties: Successful Transfer from SPC/E

Grotz

Schwierz

2021

Preprint

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Magnesium plays a vital role in a large variety of biological processes. To model such processes by molecular dynamics simulations, researchers rely on accurate force field parameters for Mg2+ and water. OPC is one of the most promising water models yielding an improved description of biomolecules in water. The aim of this work is to provide force field parameters for Mg2+ that lead to accurate simulation results in combination with OPC water. Using twelve different Mg2+ parameter sets, that were previously optimized with different water models, we systematically assess the transferability to OPC based on a large variety of experimental properties. The results show that the Mg2+ parameters for SPC/E are transferable to OPC and closely reproduce the experimental solvation free energy, radius of the first hydration shell, coordination number, activity derivative, and binding affinity toward the phosphate oxygen on RNA. Two optimal parameter sets are presented: MicroMg yields water exchange in OPC on the microsecond timescale in agreement with experiments. NanoMg yields accelerated exchange on the nanosecond timescale and facilitates the direct observation of ion binding events for enhanced sampling purposes.

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Section: Resultscontrasting

confidence: 84%

Magnesium Force Fields for OPC Water with Accurate Solvation, Ion-Binding, and Water-Exchange Properties: Successful Transfer from SPC/E

Grotz

Schwierz

2021

Preprint

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“…As further contributions, also the decisive role of local interactions in combination with charge transfer effects were discussed, ,,,,,− which directly point to modified electrostatics in terms of a so-called charge scaling concept for atomistic molecular dynamics (MD) simulations . Herewith, one can empirically introduce the missing polarizability of ions in MD simulations, such that the reduced charge of an ion can be written as with the dielectric constant ϵ r of the solution as consequence of polarization and charge transfer effects. , In addition to such static continuum approaches, also fully polarizable force fields in terms of Drude oscillators or bead–spring models for atomistic and coarse-grained MD simulations were introduced. − Thus, all of these approaches focus on fluctuating charge behavior which underlines the crucial role of ion–solvent interactions. In summary, one can conclude that the electronic polarizability in combination with charge transfer effects are important contributions for a more reliable description of specific ion effects in terms of the binding behavior, pairing effects, and ion distributions. − Moreover, it was also discussed that charges in solution introduce a locally varying dielectric permittivity which further affects the electrostatic interactions. , The corresponding higher order arrangement of the solvent molecules changes the local viscosity of the solution, such that also the dynamic behavior of the species is modified .…”

Section: Specific Ion Effects: Recent Resultsmentioning

confidence: 99%

Specific Ion Effects in Different Media: Current Status and Future Challenges

Miranda‐Quintana

Smiatek

2021

J. Phys. Chem. B

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We discuss the current state of research as well as the future challenges for a deeper understanding of specific ion effects in protic and aprotic solvents as well as various additional media. Despite recent interest in solute or interfacial effects, we focus exclusively on the specific properties of ions in bulk electrolyte solutions. Corresponding results show that many mechanisms remain unknown for these simple media, although theoretical, computational, and experimental studies have provided some insights into explaining individual observations. In particular, the importance of local interactions and electronic properties is emphasized, which enabled a more consistent interpretation of specific ion effects over the past years. Despite current insufficient knowledge, we also discuss future challenges in relation to dynamic properties as well as the influence of different concentrations, different solvents, and solute contributions to gain a deeper understanding of specific ion effects for technological applications.

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“…Thus, very recently, Loche et al using a fine-tuned nonpolarizable optimized FF simulated aqueous solutions of NaCl, KCl, NaBr, and KBr up to a concentration of 5 mol/kg. 16 Their new optimized FF reproduced the density, dielectric decrement, and ion conductivity variations of the solution over the entire concentration range that was studied. What about simulations of inhomogeneous systems, where inclusion of explicit polarization seems to be important?…”

Section: ■ Force Fieldsmentioning

confidence: 99%

“…After all, the pairwise potentials still contain a large number of parameters that can be fine-tuned. Thus, very recently, Loche et al using a fine-tuned nonpolarizable optimized FF simulated aqueous solutions of NaCl, KCl, NaBr, and KBr up to a concentration of 5 mol/kg . Their new optimized FF reproduced the density, dielectric decrement, and ion conductivity variations of the solution over the entire concentration range that was studied.…”

Section: Force Fieldsmentioning

confidence: 99%

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

Berkowitz

2021

J. Phys. Chem. B

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We describe here simulations of aqueous salt solutions that are performed using an explicit charge transfer force field. The emphasis of the discussion is on the calculation of a dynamical property of the solutions: selfdiffusion of water. While force fields that are based on pairwise additive potentials or on potentials with explicit inclusion of polarization or with scaled charges can provide at best a qualitative agreement with experiments, force fields with explicit inclusion of charge transfer can produce quantitative agreement with experiment for NaCl and KCl solutions. We argue that a force field with explicit charge transfer contains new physics absent in the previously used force fields described in recent reviews of molecular simulations of aqueous electrolytes.

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Transferable Ion Force Fields in Water from a Simultaneous Optimization of Ion Solvation and Ion–Ion Interaction

Cited by 49 publications

References 56 publications

Magnesium Force Fields for OPC Water with Accurate Solvation, Ion-Binding, and Water-Exchange Properties: Successful Transfer from SPC/E

Magnesium Force Fields for OPC Water with Accurate Solvation, Ion-Binding, and Water-Exchange Properties: Successful Transfer from SPC/E

Specific Ion Effects in Different Media: Current Status and Future Challenges

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

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