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Statistical mechanics of polarizable force fields based on classical Drude oscillators with dynamical propagation by the dual-thermostat extended Lagrangian

Chetan Rupakheti, Guillaume Lamoureux, Alexander D. MacKerell, Benoı̂t Roux

2020The Journal of Chemical Physics68 citationsDOIOpen Access PDF

Abstract

Polarizable force fields based on classical Drude oscillators offer a practical and computationally efficient avenue to carry out molecular dynamics (MD) simulations of large biomolecular systems. To treat the polarizable electronic degrees of freedom, the Drude model introduces a virtual charged particle that is attached to its parent nucleus via a harmonic spring. Traditionally, the need to relax the electronic degrees of freedom for each fixed set of nuclear coordinates is achieved by performing an iterative self-consistent field (SCF) calculation to satisfy a selected tolerance. This is a computationally demanding procedure that can increase the computational cost of MD simulations by nearly one order of magnitude. To avoid the costly SCF procedure, a small mass is assigned to the Drude particles, which are then propagated as dynamic variables during the simulations via a dual-thermostat extended Lagrangian algorithm. To help clarify the significance of the dual-thermostat extended Lagrangian propagation in the context of the polarizable force field based on classical Drude oscillators, the statistical mechanics of a dual-temperature canonical ensemble is formulated. The conditions for dynamically maintaining the dual-temperature properties in the case of the classical Drude oscillator are analyzed using the generalized Langevin equation.

Topics & Concepts

ThermostatHarmonic oscillatorDegrees of freedom (physics and chemistry)PolarizabilityForce field (fiction)Statistical physicsStatistical mechanicsPhysicsDrude modelClassical mechanicsQuantum mechanicsThermodynamicsMoleculeProtein Structure and DynamicsSpectroscopy and Quantum Chemical StudiesQuantum, superfluid, helium dynamics
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