Frequency Dependent Non- Thermal Effects of Oscillating Electric Fields in the Microwave Region on the Properties of a Solvated Lysozyme System: A Molecular Dynamics Study

Floros, Stelios; Liakopoulou-Kyriakides, M.; Karatasos, K.; Georgios, Papadopoulos E

doi:10.1371/journal.pone.0169505

Cited by 13 publications

(5 citation statements)

References 50 publications

(49 reference statements)

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“…The second set of MD simulations comprised equilibrium NVT simulations to determine the static dielectric constant from the total dipole moment induced in the sample by an external static electric field 13 . In these simulations electric fields with strengths ranging from 0.0 to 0.01 V/Å, with a step of 0.001 V/Å, were applied in the x direction.…”

Section: Computational Detailsmentioning

confidence: 99%

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

Afify

Sweatman

2018

The Journal of Chemical Physics

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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.

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Section: Computational Detailsmentioning

confidence: 99%

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

Afify

Sweatman

2018

The Journal of Chemical Physics

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“…It has been suggested that understanding the non-thermal effect of microwave field with the systems under consideration is of great importance to the development of novel separation technologies 28 , 29 , selective heating, heterogeneous catalysis 30 , 31 , and in solid phase organic synthesis (SPOS) 32 – 35 . Over the past decades, a number of experiential techniques 21 , 36 – 41 and theoretical methods 42 – 45 have been carried out to illustrate the non-thermal microwave effects. Investigating the variation of dielectric property caused by external electric fields (and therefore of the microwave power) is an effective way to understand the microwave non-thermal mechanism 46 .…”

Section: Introductionmentioning

confidence: 99%

Investigation of Nonlinear Output-Input Microwave Power of DMSO-Ethanol Mixture by Molecular Dynamics Simulation

Zhou

Cheng

Sun

et al. 2018

Sci Rep

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The nonlinear response of output-input microwave power for DMSO-ethanol mixture, which was exhibited as the direct evidence of non-thermal effect in experiment, was investigated by molecular dynamics simulation. Effects of microwave field on the mixture were evaluated from the alteration in structure, transport, hydrogen bonding dynamics and intermolecular interaction energy. Increasing the strength of the microwave field did not lead to any markedly conformational change, but decrease the diffusion coefficient. Prolonged hydrogen bonding lifetimes, which caused by the redistribution of microwave energy, was also detected. Distinct threshold effect was observed, which was consistent with the behavior in the experiment.

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“…Our second approach for the determination of the static dielectric constant of MEA involves equilibration of the liquid under an externally applied static electric field 20,21 . According to this method the magnitude of the total dipole moment induced by an external static electric field of intensity E is given by Equation 2.…”

Section: Calculation Of Static Dielectric Constants Using the Applmentioning

confidence: 99%

Molecular dynamics simulation of microwave heating of liquid monoethanolamine (MEA): An evaluation of existing force fields

Afify

Sweatman

2018

The Journal of Chemical Physics

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We present a complete classical molecular dynamics (MD) study of the dielectric heating of liquid monoethanolamine (MEA) at microwave (MW) frequencies ranging from 1.0 to 10.0 GHz. The detailed dielectric properties predicted by a series of existing empirical force fields of MEA were carefully compared to experimental results. We find that all the evaluated force fields were unable to accurately predict experimental static dielectric constant, frequency-dependent dielectric spectra, and MW heating profiles of liquid MEA, although GROMOS-aa (all-atom GROningen molecular simulation) is the most accurate of those tested. With an isotropic scaling of partial atomic charges, the modified GROMOS-aa and OPLS-aa (all-atom optimized potentials for liquid simulations) force fields could accurately reproduce the experimental static dielectric constant and frequency-dependent dielectric spectra, but they failed to predict MW heating rates directly from MD heating simulations. Thus, the recently presented approach [F. J. Salas et al., J. Chem. Theory Comput. 11, 683 (2015); A. P. de la Luz et al., ibid. 11, 2792 (2015)] to tune existing force fields is not an ideal approach to produce force fields suitable for accurate dielectric heating studies.

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Frequency Dependent Non- Thermal Effects of Oscillating Electric Fields in the Microwave Region on the Properties of a Solvated Lysozyme System: A Molecular Dynamics Study

Cited by 13 publications

References 50 publications

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

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

Investigation of Nonlinear Output-Input Microwave Power of DMSO-Ethanol Mixture by Molecular Dynamics Simulation

Molecular dynamics simulation of microwave heating of liquid monoethanolamine (MEA): An evaluation of existing force fields

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