Litcius/Paper detail

DL_FFLUX: A Parallel, Quantum Chemical Topology Force Field

Benjamin C. B. Symons, Michael Bane, Paul L. A. Popelier

2021Journal of Chemical Theory and Computation46 citationsDOIOpen Access PDF

Abstract

atoms), DL_FFLUX is shown to add minimal computational cost to the standard DL_POLY package. In fact, the optimization of the electrostatics in DL_FFLUX means that, when high-rank multipole moments are enabled, DL_FFLUX is up to 1.25× faster than standard DL_POLY. The parallel DL_FFLUX preserves the quality of the scaling of MPI implementation in standard DL_POLY. For the first time, it is feasible to use the full capability of DL_FFLUX to study systems that are large enough to be of real-world interest. For example, a fully flexible, high-rank polarized (up to and including quadrupole moments) 1 ns simulation of a system of 10 125 atoms (3375 water molecules) takes 30 h (wall time) on 18 cores.

Topics & Concepts

Multipole expansionDipoleComputational scienceComputer scienceFast multipole methodForce field (fiction)QuantumHyperpolarizabilityMolecular dynamicsTopology (electrical circuits)PolarizabilityAlgorithmComputational chemistryPhysicsChemistryMoleculeQuantum mechanicsMathematicsCombinatoricsMachine Learning in Materials ScienceComputational Drug Discovery MethodsProtein Structure and Dynamics