posted on 2022-06-09, 21:43authored bySaikat Mukherjee, Mario Barbatti
The
problem associated with the zero-point energy (ZPE) leak in
classical trajectory calculations is well known. Since ZPE is a manifestation
of the quantum uncertainty principle, there are no restrictions on
energy during the classical propagation of nuclei. This phenomenon
can lead to unphysical results, such as forming products without the
ZPE in the internal vibrational degrees of freedom (DOFs). The ZPE
leakage also permits reactions below the quantum threshold for the
reaction. We have developed a new Hessian-free method, inspired by
the Lowe-Andersen thermostat model, to prevent energy dipping below
a threshold in the local-pair (LP) vibrational DOFs. The idea is to
pump the leaked energy to the corresponding local vibrational mode
taken from the other vibrational DOFs. We have applied the new correction
protocol on the ab-initio ground-state molecular dynamics simulation
of the water dimer (H2O)2, which dissociates
due to unphysical ZPE spilling from high-frequency OH modes. The LP-ZPE
method has been able to prevent the ZPE spilling of the OH stretching
modes by pumping back the leaked energy into the corresponding modes,
while this energy is taken from the other modes of the dimer itself,
keeping the system as a microcanonical ensemble.