A hybrid formalism combining fluctuating hydrodynamics and generalized Langevin dynamics for the simulation of nanoparticle thermal motion in an incompressible fluid medium

Molecular Physics

Volumn 110, Issue 11-12, 2012, Pages 1057-1067

  Uma, Balakrishnan ^a,b   Eckmann, David M ^a,b   Ayyaswamy, Portonovo S ^b   Radhakrishnan, Ravi ^b  

^a UNIVERSITY OF PENNSYLVANIA   (United States)

^b UNIVERSITY OF PENNSYLVANIA   (United States)

Author keywords

hydrodynamic interactions; non Markovian approach; Ornstein Uhlenbeck process; thermostat; velocity autocorrelation

Indexed keywords

ADDED MASS; ANALYTICAL RESULTS; ARBITRARY GEOMETRY; ARBITRARY LAGRANGIAN EULERIAN; BIOLOGICAL REACTION; COMPUTATIONAL APPROACH; CYLINDRICAL VESSELS; EQUIPARTITION; EQUIPARTITION OF ENERGY; FINITE ELEMENT METHOD FEM; FINITE TEMPERATURES; HYBRID APPROACH; HYBRID FORMALISM; HYBRID SCHEME; HYDRODYNAMIC INTERACTION; INCOMPRESSIBLE FLUID; INCOMPRESSIBLE NEWTONIAN FLUID; LANGEVIN; LANGEVIN DYNAMICS; MARKOVIAN; MEAN SQUARED DISPLACEMENT; NON-MARKOVIAN; ORNSTEIN-UHLENBECK; ORNSTEIN-UHLENBECK PROCESS; RECEPTOR-LIGAND INTERACTIONS; THERMAL EQUILIBRIUMS; THERMAL MOTION; VELOCITY AUTOCORRELATION FUNCTIONS; VELOCITY AUTOCORRELATIONS; VESSEL WALLS;

ADHESION; DYNAMICS; EQUATIONS OF MOTION; FINITE ELEMENT METHOD; NANOPARTICLES; THERMOSTATS;

HYDRODYNAMICS;

EID: 84862566531     PISSN: 00268976     EISSN: 13623028     Source Type: Journal    
DOI: 10.1080/00268976.2012.663510     Document Type: Conference Paper

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