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Main Authors: Kusmierek, Kasper J., Schemmer, Max, Mahmoodian, Sahand, Hammerer, Klemens
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2412.14930
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author Kusmierek, Kasper J.
Schemmer, Max
Mahmoodian, Sahand
Hammerer, Klemens
author_facet Kusmierek, Kasper J.
Schemmer, Max
Mahmoodian, Sahand
Hammerer, Klemens
contents The transmission of light through an ensemble of two-level emitters in a one-dimensional geometry is commonly described by one of two emblematic models of quantum electrodynamics (QED): the driven-dissipative Dicke model or the Maxwell-Bloch equations. Both exhibit distinct features of phase transitions and phase separations, depending on system parameters such as optical depth and external drive strength. Here, we explore the crossover between these models via a parent spin model from bidirectional waveguide QED, by varying positional disorder among emitters. Solving mean-field equations and employing a second-order cumulant expansion for the unidirectional model -- equivalent to the Maxwell-Bloch equations -- we study phase diagrams, the emitter's inversion, and transmission depending on optical depth, drive strength, and spatial disorder. We find in the thermodynamic limit the emergence of phase separation with a critical value that depends on the degree of spatial order but is independent of Doppler broadening effects. Even far from the thermodynamic limit, this critical value marks a special point in the emitter's correlation landscape of the unidirectional model and is also observed as a maximum in the magnitude of inelastically transmitted photons. We conclude that a large class of effective one-dimensional systems without tight control of the emitter's spatial ordering can be effectively modeled using a unidirectional waveguide approach.
format Preprint
id arxiv_https___arxiv_org_abs_2412_14930
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Emergence of unidirectionality and phase separation in optically dense emitter ensembles
Kusmierek, Kasper J.
Schemmer, Max
Mahmoodian, Sahand
Hammerer, Klemens
Quantum Physics
Atomic Physics
The transmission of light through an ensemble of two-level emitters in a one-dimensional geometry is commonly described by one of two emblematic models of quantum electrodynamics (QED): the driven-dissipative Dicke model or the Maxwell-Bloch equations. Both exhibit distinct features of phase transitions and phase separations, depending on system parameters such as optical depth and external drive strength. Here, we explore the crossover between these models via a parent spin model from bidirectional waveguide QED, by varying positional disorder among emitters. Solving mean-field equations and employing a second-order cumulant expansion for the unidirectional model -- equivalent to the Maxwell-Bloch equations -- we study phase diagrams, the emitter's inversion, and transmission depending on optical depth, drive strength, and spatial disorder. We find in the thermodynamic limit the emergence of phase separation with a critical value that depends on the degree of spatial order but is independent of Doppler broadening effects. Even far from the thermodynamic limit, this critical value marks a special point in the emitter's correlation landscape of the unidirectional model and is also observed as a maximum in the magnitude of inelastically transmitted photons. We conclude that a large class of effective one-dimensional systems without tight control of the emitter's spatial ordering can be effectively modeled using a unidirectional waveguide approach.
title Emergence of unidirectionality and phase separation in optically dense emitter ensembles
topic Quantum Physics
Atomic Physics
url https://arxiv.org/abs/2412.14930