Publication record · 18.cifr/1984.berendsen.thermostat-barostat

Molecular dynamics with coupling to an external bath

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H. J. C. Berendsen (University of Groningen), J. P. M. Postma (University of Groningen), W. F. van Gunsteren (University of Groningen), A. DiNola (University of Groningen), J. R. Haak (University of Groningen)

RAI18.cifr/1984.berendsen.thermostat-barostat

The Journal of Chemical Physics· 1984· doi:10.1063/1.448118

In molecular dynamics (MD) simulations the need often arises to maintain such parameters as temperature or pressure rather than energy and volume, or to impose gradients for studying transport properties in nonequilibrium MD. A method is described to realize coupling to an external bath with constant temperature or pressure with adjustable time constants for the coupling. The method is easily extendable to other variables and to gradients, and can be applied also to polyatomic molecules involving internal constraints. The influence of coupling time constants on dynamical variables is evaluated. A leap-frog algorithm is presented for the general case involving constraints with coupling to both a constant temperature and a constant pressure bath.

molecular dynamicsthermostatbarostattemperature couplingpressure couplingleap-frog

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Classical MD conserves energy and volume (NVE), but experiments occur at constant T and P. Ad hoc velocity rescaling is discontinuous and unphysical; extended-Lagrangian methods are complex. The Berendsen scheme offers a simple, cheap, and robust way to equilibrate and run NVT/NPT simulations.

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The Berendsen method introduces weak coupling to an external bath via first-order relaxation, providing smooth continuous control over temperature and pressure with a user-adjustable time constant tau. Unlike abrupt velocity rescaling, the coupling strength is tunable, spanning from microcanonical (tau→∞) to strongly damped behavior. The unified leap-frog formulation handles simultaneous T and P coupling with molecular constraints.

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