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Main Authors: Zeron, I. M., Gonzalez, M. A., Errani, E., Vega, C., Abascal, J. L. F.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2401.13158
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author Zeron, I. M.
Gonzalez, M. A.
Errani, E.
Vega, C.
Abascal, J. L. F.
author_facet Zeron, I. M.
Gonzalez, M. A.
Errani, E.
Vega, C.
Abascal, J. L. F.
contents Many important processes affecting the Earth's climate are determined by the physical properties of seawater. Desalination of seawater is a significant source of drinking wate.Since the physical properties of seawater governing these processes depend on the molecular interactions among its components, a deeper knowledge of seawater at the molecular level is needed. However MD studies reporting the physical properties of seawater are currently lacking. This is probably due to the usual perception of the seawater composition being too complex to approach.This point of view ignores the fact that physical properties of seawater are dependent on a single parameter representing the composition, namely the salinity. This is because the relative proportions of any two major constituents of seasalt are always the same. An obstacle to performing MD simulations of seawater could have been the unavailability of a satisfactory force field representing the interactions between water molecules and dissolved substances. This drawback has recently been overcome with the proposal of the Madrid-2019 FF.Here we show for the first time that MD simulations of seawater are feasible. We have performed MD simulations of a system, the composition of which is close to the average composition of standard seawater and with the molecular interactions given by the Madrid-2019 force field. We are able to provide quantitative or semiquantitative predictions for a number of relevant physical properties of seawater for temperatures and salinities from the oceanographic range to those relevant to desalination processes. The computed magnitudes include static (density), dynamical (viscosity and diffusion coefficients), structural (ionic hydration, ion-ion distribution functions) and interfacial (surface tension) properties.
format Preprint
id arxiv_https___arxiv_org_abs_2401_13158
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle In Silico Seawater
Zeron, I. M.
Gonzalez, M. A.
Errani, E.
Vega, C.
Abascal, J. L. F.
Chemical Physics
Many important processes affecting the Earth's climate are determined by the physical properties of seawater. Desalination of seawater is a significant source of drinking wate.Since the physical properties of seawater governing these processes depend on the molecular interactions among its components, a deeper knowledge of seawater at the molecular level is needed. However MD studies reporting the physical properties of seawater are currently lacking. This is probably due to the usual perception of the seawater composition being too complex to approach.This point of view ignores the fact that physical properties of seawater are dependent on a single parameter representing the composition, namely the salinity. This is because the relative proportions of any two major constituents of seasalt are always the same. An obstacle to performing MD simulations of seawater could have been the unavailability of a satisfactory force field representing the interactions between water molecules and dissolved substances. This drawback has recently been overcome with the proposal of the Madrid-2019 FF.Here we show for the first time that MD simulations of seawater are feasible. We have performed MD simulations of a system, the composition of which is close to the average composition of standard seawater and with the molecular interactions given by the Madrid-2019 force field. We are able to provide quantitative or semiquantitative predictions for a number of relevant physical properties of seawater for temperatures and salinities from the oceanographic range to those relevant to desalination processes. The computed magnitudes include static (density), dynamical (viscosity and diffusion coefficients), structural (ionic hydration, ion-ion distribution functions) and interfacial (surface tension) properties.
title In Silico Seawater
topic Chemical Physics
url https://arxiv.org/abs/2401.13158