English

Photo-induced dynamics with continuous and discrete quantum baths

Quantum Physics 2024-09-04 v3

Abstract

The ultrafast quantum dynamics of photophysical processes in complex molecules is an extremely challenging computational problem with a wide variety of fascinating applications in quantum chemistry and biology. Inspired by recent developments in open quantum systems, we introduce a pure-state unraveled hybrid-bath method that describes a continuous environment via a set of discrete, effective bosonic degrees of freedom using a Markovian embedding. Our method is capable of describing both, a continuous spectral density and sharp peaks embedded into it. Thereby, we overcome the limitations of previous methods, which either capture long-time memory effects using the unitary dynamics of a set of discrete vibrational modes or use memoryless Markovian environments employing a Lindblad or Redfield master equation. We benchmark our method against two paradigmatic problems from quantum chemistry and biology. We demonstrate that compared to unitary descriptions, a significantly smaller number of bosonic modes suffices to describe the excitonic dynamics accurately, yielding a computational speed-up of nearly an order of magnitude. Furthermore, we take into account explicitly the effect of a δ\delta-peak in the spectral density of a light-harvesting complex, demonstrating the strong impact of the long-time memory of the environment on the dynamics.

Keywords

Cite

@article{arxiv.2406.07047,
  title  = {Photo-induced dynamics with continuous and discrete quantum baths},
  author = {Zhaoxuan Xie and Mattia Moroder and Ulrich Schollwöck and Sebastian Paeckel},
  journal= {arXiv preprint arXiv:2406.07047},
  year   = {2024}
}

Comments

Minor changes after publication

R2 v1 2026-06-28T17:00:57.739Z