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An Investigation into the Approximations Used in Wave Packet Molecular Dynamics for the Study of Warm Dense Matter

William A. Angermeier

2021MDPI (MDPI AG)10 citationsDOIOpen Access PDF

Abstract

Wave packet molecular dynamics (WPMD) has recently received a lot of attention as a computationally fast tool with which to study dynamical processes in warm dense matter beyond the Born–Oppenheimer approximation. These techniques, typically, employ many approximations to achieve computational efficiency while implementing semi-empirical scaling parameters to retain accuracy. We investigated three of the main approximations ubiquitous to WPMD: a restricted basis set, approximations to exchange, and the lack of correlation. We examined each of these approximations in regard to atomic and molecular hydrogen in addition to a dense hydrogen plasma. We found that the biggest improvement to WPMD comes from combining a two-Gaussian basis with a semi-empirical correction based on the valence-bond wave function. A single parameter scales this correction to match experimental pressures of dense hydrogen. Ultimately, we found that semi-empirical scaling parameters are necessary to correct for the main approximations in WPMD. However, reducing the scaling parameters for more ab-initio terms gives more accurate results and displays the underlying physics more readily.

Topics & Concepts

ScalingWave packetStatistical physicsMolecular dynamicsGaussianWave functionBasis setApproximations of πAb initioComputer scienceBasis functionPhysicsMathematicsApplied mathematicsQuantum mechanicsGeometryDensity functional theorySpectroscopy and Laser ApplicationsQuantum, superfluid, helium dynamicsCold Atom Physics and Bose-Einstein Condensates