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 s...
We discuss the use of a Langevin equation with a colored (correlated) noise to perform constant-temp...
Molecular dynamics can be used as a very effective, general-purpose approach to gen-erate atomic con...
In this work we compare and characterize the behavior of Langevin and dissipative particle dynamics ...
A direct numerical simulation (DNS) procedure is employed to study the thermal motion of a nanoparti...
In this article, we present several algorithms for stochastic dynamics, including Langevin dynamics ...
Recently, we have shown how a colored-noise Langevin equation can be used in the context of molecula...
AbstractAbstract Recently, the authors introduced a comprehensive framework to use a custom-tailored...
The theory of Brownian motion is a cornerstone of modern physics. In this thesis, we introduce a non...
Poiseuille flow of a liquid in a nano-channel is simulated by molecular dynamics by embedding the fl...
AbstractWe examine the formulation and numerical treatment of dissipative particle dynamics (DPD) an...
Computer simulation of complex nonlinear and disordered phenomena from materials science is rapidly ...
We discuss the use of a Langevin equation with a colored (correlated) noise to perform constant-temp...
This paper expands a recent proposal by the authors to rederive the Langevin equation for a test par...
Nonequilibrium molecular dynamics (NEMD) has been extensively used to study thermal transport at var...
Nonequilibrium molecular dynamics (NEMD) has been extensively used to study thermal transport at var...
We discuss the use of a Langevin equation with a colored (correlated) noise to perform constant-temp...
Molecular dynamics can be used as a very effective, general-purpose approach to gen-erate atomic con...
In this work we compare and characterize the behavior of Langevin and dissipative particle dynamics ...
A direct numerical simulation (DNS) procedure is employed to study the thermal motion of a nanoparti...
In this article, we present several algorithms for stochastic dynamics, including Langevin dynamics ...
Recently, we have shown how a colored-noise Langevin equation can be used in the context of molecula...
AbstractAbstract Recently, the authors introduced a comprehensive framework to use a custom-tailored...
The theory of Brownian motion is a cornerstone of modern physics. In this thesis, we introduce a non...
Poiseuille flow of a liquid in a nano-channel is simulated by molecular dynamics by embedding the fl...
AbstractWe examine the formulation and numerical treatment of dissipative particle dynamics (DPD) an...
Computer simulation of complex nonlinear and disordered phenomena from materials science is rapidly ...
We discuss the use of a Langevin equation with a colored (correlated) noise to perform constant-temp...
This paper expands a recent proposal by the authors to rederive the Langevin equation for a test par...
Nonequilibrium molecular dynamics (NEMD) has been extensively used to study thermal transport at var...
Nonequilibrium molecular dynamics (NEMD) has been extensively used to study thermal transport at var...
We discuss the use of a Langevin equation with a colored (correlated) noise to perform constant-temp...
Molecular dynamics can be used as a very effective, general-purpose approach to gen-erate atomic con...
In this work we compare and characterize the behavior of Langevin and dissipative particle dynamics ...