Related papers: Spin-only dynamics of the multi-species nonreciprocal Dicke model

Spin-only dynamics of the multi-species nonreciprocal Dicke model

URL: http://arxiv.org/abs/2507.07960v1
Date: Thu, 10 Jul 2025 17:41:46 GMT
Title: Spin-only dynamics of the multi-species nonreciprocal Dicke model
Authors: Joseph Jachinowski, Peter B. Littlewood,
Abstract summary: Hepp-Lieb-Dicke model is ubiquitous in cavity quantum electrodynamics.<n>We study a variation of the open Dicke model which realizes mediated nonreciprocal interactions between spin species.<n>We find signatures of phase transitions even for small system sizes.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: The Hepp-Lieb-Dicke model is ubiquitous in cavity quantum electrodynamics, describing spin-cavity coupling which does not conserve excitation number. Coupling the closed spin-cavity system to an environment realizes the open Dicke model, and by tuning the structure of the environment or the system-environment coupling, interesting spin-only models can be engineered. In this work, we focus on a variation of the multi-species open Dicke model which realizes mediated nonreciprocal interactions between the spin species and, consequently, an interesting dynamical limit-cycle phase. In particular, we improve upon adiabatic elimination and, instead, employ a Redfield master equation in order to describe the effective dynamics of the spin-only system. We assess this approach at the mean-field level, comparing it both to adiabatic elimination and the full spin-cavity model, and find that the predictions are sensitive to the presence of single-particle incoherent decay. Additionally, we clarify the symmetries of the model and explore the dynamical limit-cycle phase in the case of explicit parity-time-symmetry breaking, finding a region of phase coexistence terminating at an codimension-two exceptional point. Lastly, we go beyond mean-field theory by exact numerical diagonalization of the master equation, appealing to permutation symmetry in order to increase the size of accessible systems. We find signatures of phase transitions even for small system sizes.

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