Investigating the Stability and Accuracy of a Classical Mapping Variable Hamiltonian for Nonadiabatic Quantum Dynamics
2021, Volume 26, Number 2, pp. 131-146
Author(s): Eklund E. C., Ananth N.
Author(s): Eklund E. C., Ananth N.
Previous work has shown that by using the path integral representation of quantum
mechanics and by mapping discrete electronic states to continuous Cartesian variables, it is
possible to derive an exact quantum “mapping variable” ring-polymer (MV-RP) Hamiltonian.
The classical molecular dynamics generated by this MV-RP Hamiltonian can be used to
calculate equilibrium properties of multi-level quantum systems exactly, and to approximate
real-time thermal correlation functions (TCFs). Here, we derive mixed time-slicing forms of the
MV-RP Hamiltonian where different modes of a multi-level system are quantized to different
extents. We explore the accuracy of the approximate quantum dynamics generated by these
Hamiltonians through numerical calculation of quantum real-time TCFs for a range of model
nonadiabatic systems, where two electronic states are coupled to a single nuclear degree of
freedom. Interestingly, we find that the dynamics generated by an MV-RP Hamiltonian with
all modes treated classically is more stable across all model systems considered here than mixed
quantization approaches. Further, we characterize nonadiabatic dynamics in the 6D phase space
of our classical-limit MV-RP Hamiltonian using Lagrangian descriptors to identify stable and
unstable manifolds.
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