English

Surface hopping methodology in laser-driven molecular dynamics

Chemical Physics 2017-07-05 v2 Atomic Physics Quantum Physics

Abstract

A theoretical justification of the empirical surface hopping method for the laser-driven molecular dynamics is given utilizing the formalism of the exact factorization of the molecular wavefunction [Abedi et al., PRL 105\textbf{105}, 123002 (2010)] in its quantum-classical limit. Employing an exactly solvable H2  +\textrm H_2^{\;+}-like model system, it is shown that the deterministic classical nuclear motion on a single time-dependent surface in this approach describes the same physics as stochastic (hopping-induced) motion on several surfaces, provided Floquet surfaces are applied. Both quantum-classical methods do describe reasonably well the exact nuclear wavepacket dynamics for extremely different dissociation scenarios. Hopping schemes using Born-Oppenheimer surfaces or instantaneous Born-Oppenheimer surfaces fail completely.

Keywords

Cite

@article{arxiv.1608.08768,
  title  = {Surface hopping methodology in laser-driven molecular dynamics},
  author = {T. Fiedlschuster and J. Handt and E. K. U. Gross and R. Schmidt},
  journal= {arXiv preprint arXiv:1608.08768},
  year   = {2017}
}
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