International audienceAdaptively Restrained Molecular Dynamics (ARMD) is a recently introduced particles simulation method that switches positional degrees of freedom on and off during simulation in order to speed up calculations. In the NVE ensemble, ARMD allows users to trade between precision and speed while, in the NVT ensemble, it makes it possible to compute statistical averages faster. Despite the conceptual simplicity of the approach, however, integrating it in existing molecular dynamics packages is non-trivial, in particular since implemented potentials should a priori be rewritten to take advantage of frozen particles and achieve a speed-up. In this paper, we present novel algorithms for integrating ARMD in LAMMPS, a popular mult...
We report on a parallel version of the Fast Multipole Method (FMM) implemented in the classical mole...
Reactive molecular dynamics (MD) simulation is a powerful research tool for describing chemical reac...
We have enhanced our parallel molecular dynamics (MD) simulation software LAMMPS (Large-scale Atomic...
International audienceAdaptively Restrained Molecular Dynamics (ARMD) is a recently introduced parti...
International audienceAdaptively Restrained Molecular dynamics (ARMD) allows users to perform more i...
International audienceForce computations are one of the most time consuming part in performing Molec...
Molecular Dynamics (MD) is often used to simulate large and complex systems. Although, simulating su...
Les méthodes de dynamique moléculaire (MD pour Molecular Dynamics en anglais) sont utilisées pour si...
International audienceInteraction potentials used in particle simulations are typically written as a...
International audienceIn this paper, we explore the use of Adaptively Restrained (AR) particles for ...
International audienceModern parallel architectures require applications to generate massive paralle...
International audienceThe computation of long-range potentials is one of the demanding tasks in Mole...
In molecular dynamics simulations we can often increase the time step by imposing constraints on bon...
The ability to model molecular systems on a computer has become a crucial tool for chemists. Molecul...
We report on a parallel version of the Fast Multipole Method (FMM) implemented in the classical mole...
Reactive molecular dynamics (MD) simulation is a powerful research tool for describing chemical reac...
We have enhanced our parallel molecular dynamics (MD) simulation software LAMMPS (Large-scale Atomic...
International audienceAdaptively Restrained Molecular Dynamics (ARMD) is a recently introduced parti...
International audienceAdaptively Restrained Molecular dynamics (ARMD) allows users to perform more i...
International audienceForce computations are one of the most time consuming part in performing Molec...
Molecular Dynamics (MD) is often used to simulate large and complex systems. Although, simulating su...
Les méthodes de dynamique moléculaire (MD pour Molecular Dynamics en anglais) sont utilisées pour si...
International audienceInteraction potentials used in particle simulations are typically written as a...
International audienceIn this paper, we explore the use of Adaptively Restrained (AR) particles for ...
International audienceModern parallel architectures require applications to generate massive paralle...
International audienceThe computation of long-range potentials is one of the demanding tasks in Mole...
In molecular dynamics simulations we can often increase the time step by imposing constraints on bon...
The ability to model molecular systems on a computer has become a crucial tool for chemists. Molecul...
We report on a parallel version of the Fast Multipole Method (FMM) implemented in the classical mole...
Reactive molecular dynamics (MD) simulation is a powerful research tool for describing chemical reac...
We have enhanced our parallel molecular dynamics (MD) simulation software LAMMPS (Large-scale Atomic...