The Coupled-Trajectory Mixed Quantum-Classical Algorithm: A Deconstruction
Abstract
We analyze a mixed quantum-classical algorithm recently derived from the exact factorization equations [Min, Agostini, Gross, PRL {\bf 115}, 073001 (2015)] to show the role of the different terms in the algorithm in bringing about decoherence and wavepacket branching. The algorithm has the structure of Ehrenfest equations plus a "coupled-trajectory" term for both the electronic and nuclear equations, and we analyze the relative roles played by the different non-adiabatic terms in these equations, including how they are computed in practise. In particular, we show that while the coupled-trajectory term in the electronic equation is essential in yielding accurate dynamics, that in the nuclear equation has a much smaller effect. A decoherence time is extracted from the electronic equations and compared with that of augmented fewest-switches surface-hopping. We revisit a series of non-adiabatic Tully model systems to illustrate our analysis.
Cite
@article{arxiv.1805.03534,
title = {The Coupled-Trajectory Mixed Quantum-Classical Algorithm: A Deconstruction},
author = {Graeme H. Gossel and Federica Agostini and Neepa T. Maitra},
journal= {arXiv preprint arXiv:1805.03534},
year = {2018}
}
Comments
17 pages, 13 figures