Generalized Langevin Dynamics of a Nanoparticle Using a Finite Element Approach: Thermostating with Correlated Noise

Overview

Journal J Chem Phys

Publisher American Institute of Physics

Specialties Biophysics
Chemistry

Date 2011 Sep 29

PMID 21950847

Citations 11

Authors

B Uma

T N Swaminathan

P S Ayyaswamy

D M Eckmann

R Radhakrishnan

Affiliations

Soon will be listed here.

Abstract

A direct numerical simulation (DNS) procedure is employed to study the thermal motion of a nanoparticle in an incompressible Newtonian stationary fluid medium with the generalized Langevin approach. We consider both the Markovian (white noise) and non-Markovian (Ornstein-Uhlenbeck noise and Mittag-Leffler noise) processes. Initial locations of the particle are at various distances from the bounding wall to delineate wall effects. At thermal equilibrium, the numerical results are validated by comparing the calculated translational and rotational temperatures of the particle with those obtained from the equipartition theorem. The nature of the hydrodynamic interactions is verified by comparing the velocity autocorrelation functions and mean square displacements with analytical results. Numerical predictions of wall interactions with the particle in terms of mean square displacements are compared with analytical results. In the non-Markovian Langevin approach, an appropriate choice of colored noise is required to satisfy the power-law decay in the velocity autocorrelation function at long times. The results obtained by using non-Markovian Mittag-Leffler noise simultaneously satisfy the equipartition theorem and the long-time behavior of the hydrodynamic correlations for a range of memory correlation times. The Ornstein-Uhlenbeck process does not provide the appropriate hydrodynamic correlations. Comparing our DNS results to the solution of an one-dimensional generalized Langevin equation, it is observed that where the thermostat adheres to the equipartition theorem, the characteristic memory time in the noise is consistent with the inherent time scale of the memory kernel. The performance of the thermostat with respect to equilibrium and dynamic properties for various noise schemes is discussed.

Citing Articles

Nanoparticle transport phenomena in confined flows.

Radhakrishnan R, Farokhirad S, Eckmann D, Ayyaswamy P Adv Heat Transf. 2019; 51:55-129.

PMID: 31692964 PMC: 6831088. DOI: 10.1016/bs.aiht.2019.08.002.

Computational Models for Nanoscale Fluid Dynamics and Transport Inspired by Nonequilibrium Thermodynamics.

Radhakrishnan R, Yu H, Eckmann D, Ayyaswamy P J Heat Transfer. 2016; 139(3):0330011-330019.

PMID: 28035168 PMC: 5125320. DOI: 10.1115/1.4035006.

Nanoparticle stochastic motion in the inertial regime and hydrodynamic interactions close to a cylindrical wall.

Vitoshkin H, Yu H, Eckmann D, Ayyaswamy P, Radhakrishnan R Phys Rev Fluids. 2016; 1.

PMID: 27830213 PMC: 5098402. DOI: 10.1103/PhysRevFluids.1.054104.

Composite generalized Langevin equation for Brownian motion in different hydrodynamic and adhesion regimes.

Yu H, Eckmann D, Ayyaswamy P, Radhakrishnan R Phys Rev E Stat Nonlin Soft Matter Phys. 2015; 91(5):052303.

PMID: 26066173 PMC: 4467459. DOI: 10.1103/PhysRevE.91.052303.

MODELING OF A NANOPARTICLE MOTION IN A NEWTONIAN FLUID: A COMPARISON BETWEEN FLUCTUATING HYDRODYNAMICS AND GENERALIZED LANGEVIN PROCEDURES.

Uma B, Ayyaswamy P, Radhakrishnan R, Eckmann D Proc ASME Micro Nanoscale Heat Mass Transf Int Conf (2012). 2015; 2012:735-743.

PMID: 25621317 PMC: 4301268. DOI: 10.1115/MNHMT2012-75019.

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