Molecular dynamics simulations for the prediction of the dielectric spectra of alcohols, glycols and monoethanolamine

Cardona, Javier; Fartaria, Rui P. S.; Sweatman, Martin B.; Lue, Leo

doi:10.1080/08927022.2015.1055741

Cited by 29 publications

(37 citation statements)

References 93 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Another issue that warrants further exploration is the effect of scaling on the dynamic dielectric response of fluids 15,48 . Indeed, it has been recently shown that, at least for some fluids, classical non-polarizable models are able to describe the dynamic response over a wide range of frequencies, provided the simulation results are scaled to match the corresponding experimental static dielectric constant 48 . Application of our scaling approach to those systems would make for interesting future research.…”

Section: Resultsmentioning

confidence: 99%

The dielectric constant: Reconciling simulation and experiment

Jorge

Lue

2019

The Journal of Chemical Physics

Self Cite

View full text Add to dashboard Cite

In this paper, we present a simple correction scheme to improve predictions of dielectric constants by classical non-polarisable models. This scheme takes into account electronic polarisation effects, through the experimental refractive index of the liquid, and a possible mismatch between the potential energy surface (PES) and the dipole moment surface (DMS). We have described the latter effect by an empirical scaling factor on the point charges, the value of which was determined by fitting the dielectric constant of methanol. Application of the same scaling factor to existing benchmark datasets, comprising four different models and a wide range of compounds, led to remarkable improvements in the quality of the predictions. In particular, the observed systematic underestimation of the dielectric constant was eliminated by accounting for the two missing terms in standard models. We propose that this correction term be included in future development and validation efforts of classical non-polarisable models.

show abstract

Section: Resultsmentioning

confidence: 99%

The dielectric constant: Reconciling simulation and experiment

Jorge

Lue

2019

The Journal of Chemical Physics

Self Cite

View full text Add to dashboard Cite

show abstract

“…Due to the inability of most available empirical force fields to accurately predict the dielectric response of liquids, Cardona et al 2 suggested using the experimental values of static dielectric constants when computing the frequency-dependent dielectric spectra of these liquids using the Debye relaxation model 20 . Following this suggestion we used the experimental static dielectric constant of water to compute the dielectric spectra of water.…”

Section: Resultsmentioning

confidence: 99%

Classical molecular dynamics simulation of microwave heating of liquids: The case of water

Afify

Sweatman

2018

The Journal of Chemical Physics

View full text Add to dashboard Cite

We perform a complete classical molecular dynamics study of the dielectric heating of water in the microwave (MW) region. MW frequencies ranging from 1.0 to 15.0 GHz are used together with a series of well-known empirical force fields. We show that the ability of an empirical force field to correctly predict the dielectric response of liquids to MW radiation should be evaluated on the basis of a joint comparison of the predicted and experimental static dielectric constant, frequency-dependent dielectric spectra, and heating profiles. We argue that this is essential when multicomponent liquids are studied. We find that both the three-site OPC3 and four-site TIP4P-ϵ empirical force fields of water are equally superior for reproducing dielectric properties at a range of MW frequencies. Despite its poor prediction of the static dielectric constant, the well-known SPCE force field can be used to accurately describe dielectric heating of water at low MW frequencies.

show abstract

“…Our MD simulations of 50% mole‐fraction of MEG in water yielded a maximum H‐bond decay time of 60 ps (see τ R of Table ), which is in the same order as the reported dielectric relaxation time, but is not expected to be identical, since the relaxation time primarily is related to the dipole reorientation time. Using a different MD based method, the dielectric relaxation time for pure MEG at 298 K has been reported to be 87 ps when a Debye model was utilized and 71 ps when a Cole‐Davidson model was applied (where MEG was modeled using the OPLS force‐field) …”

Section: Resultsmentioning

confidence: 99%

Hydrogen bond lifetimes and statistics of aqueous mono‐, di‐ and tri‐ethylene glycol

Olsen

Kvamme

2016

AIChE Journal

View full text Add to dashboard Cite

Hydrogen bond statistics, energy distributions of hydrogen bonds and hydrogen bond lifetimes for aqueous monoethylene glycol (MEG), diethylene glycol (DEG), and triethylene glycol (TEG) were investigated at temperatures ranging from 275 to 370 K at 101.325 kPa using molecular dynamics simulations. Each individual type of hydrogen bond were studied separately to better understand how each type of hydrogen bond affected the collective behavior often measured in experiments. We also studied the effects of glycols on water–water hydrogen bond structures and lifetimes. Decay constants for hydroxyl type hydrogen bonds, as well as for water based hydrogen bonds were in the same order, thus indicating that all these hydrogen bonds play an essential role in the process of dielectric relaxation. Correlations between water hydrogen bond distances and angles were not affected markedly by adding glycols. However, hydrogen bond lifetimes increased by 9, 29, and 62 times by adding MEG, DEG, and TEG, respectively. © 2016 American Institute of Chemical Engineers AIChE J, 63: 1674–1689, 2017

show abstract

Molecular dynamics simulations for the prediction of the dielectric spectra of alcohols, glycols and monoethanolamine

Cited by 29 publications

References 93 publications

The dielectric constant: Reconciling simulation and experiment

The dielectric constant: Reconciling simulation and experiment

Classical molecular dynamics simulation of microwave heating of liquids: The case of water

Hydrogen bond lifetimes and statistics of aqueous mono‐, di‐ and tri‐ethylene glycol

Contact Info

Product

Resources

About