Related papers: Unifying the dynamical effects of quantum and classical noises

Unifying the dynamical effects of quantum and classical noises

URL: http://arxiv.org/abs/2004.13901v1
Date: Wed, 29 Apr 2020 00:34:57 GMT
Title: Unifying the dynamical effects of quantum and classical noises
Authors: Li Yu
Abstract summary: When quantum and classical noises are both present, their combined effect on a system's dynamics is not necessarily a simple sum of the two individual effects. Our formalism can determine whether there is interference between quantum and classical noises and will be able to capture and describe such interference if there is any (in a perturbative manner) This work also serves to justify simple additive treatments of quantum and classical noises, especially in the weak coupling regime.
Score: 4.592848943542229
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We develop a new master equation as a unified description of the effects of both quantum noise (system-bath interaction) and classical noise on a system's dynamics, using a two-dimensional series expansion method. When quantum and classical noises are both present, their combined effect on a system's dynamics is not necessarily a simple sum of the two individual effects. Thus previous master equations for open systems and those for classical noise, even when jointly used, may not capture the full physics. Our formalism can determine whether there is interference between quantum and classical noises and will be able to capture and describe such interference if there is any (in a perturbative manner). We find that, interestingly, second-order interference between quantum and classical noises vanishes identically. This work thus also serves to justify simple additive treatments of quantum and classical noises, especially in the weak coupling regime. For a Zeeman-splitted atom in a stochastic magnetic field interacting with an optical cavity, we use the formalism developed herein to find the overall decoherence rate between the atom's energy levels.

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