Distinctive class of dissipation-induced phase transitions and their universal characteristics

Soriente, Matteo; Heugel, Toni L.; Arimitsu, Keita; Chitra, Ramasubramanian; Zilberberg, Oded

Distinctive class of dissipation-induced phase transitions and their universal characteristics

Dateien

Soriente_2-1ngfgejs1d9wa4.pdfGröße: 1.25 MBDownloads: 110

Datum

2021

Autor:innen

Soriente, Matteo

Heugel, Toni L.

Arimitsu, Keita

Chitra, Ramasubramanian

Zilberberg, Oded

Open Access-Veröffentlichung

Open Access Gold

Sammlungen

Physik

Publikationstyp

Zeitschriftenartikel

Publikationsstatus

Published

Erschienen in

Physical Review Research. American Physical Society. 2021, 3(2), 023100. eISSN 2643-1564. Available under: doi: 10.1103/PhysRevResearch.3.023100

Zusammenfassung

Coupling a system to a nonthermal environment can profoundly affect the phase diagram of the closed system, giving rise to a special class of dissipation-induced phase transitions. Such transitions take the system out of its ground state and stabilize a higher-energy stationary state, rendering it the sole attractor of the dissipative dynamics. In this paper, we present a unifying methodology, which we use to characterize this ubiquitous phenomenology and its implications for the open system dynamics. Specifically, we analyze the closed system's phase diagram, including symmetry-broken phases, and explore their corresponding excitations' spectra. Opening the system, the environment can overwhelm the system's symmetry-breaking tendencies, and changes its order parameter. As a result, isolated distinct phases of similar order become connected, and new phase-costability regions appear. Interestingly, the excitations differ in the newly connected regions through a change in their symplectic norm, which is robust to the introduction of dissipation. As a result, by tuning the system from one phase to the other across the dissipation-stabilized region, the open system fluctuations exhibit an exceptional pointlike scenario, where the fluctuations become overdamped, only to reappear with an opposite sign in the dynamical response function of the system. The overdamped region is also associated with squeezing of the fluctuations. We demonstrate the pervasive nature of such dissipation-induced phenomena in two prominent examples, namely, in parametric resonators and in light-matter systems. Our work draws a crucial distinction between quantum phase transitions and their zero-temperature open system counterparts.

Fachgebiet (DDC)

530 Physik

Zitieren

ISO 690

SORIENTE, Matteo, Toni L. HEUGEL, Keita ARIMITSU, Ramasubramanian CHITRA, Oded ZILBERBERG, 2021. Distinctive class of dissipation-induced phase transitions and their universal characteristics. In: Physical Review Research. American Physical Society. 2021, 3(2), 023100. eISSN 2643-1564. Available under: doi: 10.1103/PhysRevResearch.3.023100

BibTex

@article{Soriente2021Disti-55006,
  year={2021},
  doi={10.1103/PhysRevResearch.3.023100},
  title={Distinctive class of dissipation-induced phase transitions and their universal characteristics},
  number={2},
  volume={3},
  journal={Physical Review Research},
  author={Soriente, Matteo and Heugel, Toni L. and Arimitsu, Keita and Chitra, Ramasubramanian and Zilberberg, Oded},
  note={Article Number: 023100}
}

RDF

<rdf:RDF
    xmlns:dcterms="http://purl.org/dc/terms/"
    xmlns:dc="http://purl.org/dc/elements/1.1/"
    xmlns:rdf="http://www.w3.org/1999/02/22-rdf-syntax-ns#"
    xmlns:bibo="http://purl.org/ontology/bibo/"
    xmlns:dspace="http://digital-repositories.org/ontologies/dspace/0.1.0#"
    xmlns:foaf="http://xmlns.com/foaf/0.1/"
    xmlns:void="http://rdfs.org/ns/void#"
    xmlns:xsd="http://www.w3.org/2001/XMLSchema#" > 
  <rdf:Description rdf:about="https://kops.uni-konstanz.de/server/rdf/resource/123456789/55006">
    <dc:creator>Zilberberg, Oded</dc:creator>
    <dspace:isPartOfCollection rdf:resource="https://kops.uni-konstanz.de/server/rdf/resource/123456789/41"/>
    <dcterms:available rdf:datatype="http://www.w3.org/2001/XMLSchema#dateTime">2021-09-24T07:44:48Z</dcterms:available>
    <dcterms:issued>2021</dcterms:issued>
    <dc:creator>Soriente, Matteo</dc:creator>
    <dc:date rdf:datatype="http://www.w3.org/2001/XMLSchema#dateTime">2021-09-24T07:44:48Z</dc:date>
    <dspace:hasBitstream rdf:resource="https://kops.uni-konstanz.de/bitstream/123456789/55006/1/Soriente_2-1ngfgejs1d9wa4.pdf"/>
    <dc:contributor>Chitra, Ramasubramanian</dc:contributor>
    <dc:language>eng</dc:language>
    <dc:contributor>Arimitsu, Keita</dc:contributor>
    <dc:creator>Heugel, Toni L.</dc:creator>
    <dcterms:hasPart rdf:resource="https://kops.uni-konstanz.de/bitstream/123456789/55006/1/Soriente_2-1ngfgejs1d9wa4.pdf"/>
    <dcterms:isPartOf rdf:resource="https://kops.uni-konstanz.de/server/rdf/resource/123456789/41"/>
    <void:sparqlEndpoint rdf:resource="http://localhost/fuseki/dspace/sparql"/>
    <dcterms:rights rdf:resource="http://creativecommons.org/licenses/by/4.0/"/>
    <dc:creator>Arimitsu, Keita</dc:creator>
    <dc:contributor>Soriente, Matteo</dc:contributor>
    <bibo:uri rdf:resource="https://kops.uni-konstanz.de/handle/123456789/55006"/>
    <dc:creator>Chitra, Ramasubramanian</dc:creator>
    <dcterms:title>Distinctive class of dissipation-induced phase transitions and their universal characteristics</dcterms:title>
    <foaf:homepage rdf:resource="http://localhost:8080/"/>
    <dc:rights>Attribution 4.0 International</dc:rights>
    <dc:contributor>Zilberberg, Oded</dc:contributor>
    <dcterms:abstract xml:lang="eng">Coupling a system to a nonthermal environment can profoundly affect the phase diagram of the closed system, giving rise to a special class of dissipation-induced phase transitions. Such transitions take the system out of its ground state and stabilize a higher-energy stationary state, rendering it the sole attractor of the dissipative dynamics. In this paper, we present a unifying methodology, which we use to characterize this ubiquitous phenomenology and its implications for the open system dynamics. Specifically, we analyze the closed system's phase diagram, including symmetry-broken phases, and explore their corresponding excitations' spectra. Opening the system, the environment can overwhelm the system's symmetry-breaking tendencies, and changes its order parameter. As a result, isolated distinct phases of similar order become connected, and new phase-costability regions appear. Interestingly, the excitations differ in the newly connected regions through a change in their symplectic norm, which is robust to the introduction of dissipation. As a result, by tuning the system from one phase to the other across the dissipation-stabilized region, the open system fluctuations exhibit an exceptional pointlike scenario, where the fluctuations become overdamped, only to reappear with an opposite sign in the dynamical response function of the system. The overdamped region is also associated with squeezing of the fluctuations. We demonstrate the pervasive nature of such dissipation-induced phenomena in two prominent examples, namely, in parametric resonators and in light-matter systems. Our work draws a crucial distinction between quantum phase transitions and their zero-temperature open system counterparts.</dcterms:abstract>
    <dc:contributor>Heugel, Toni L.</dc:contributor>
  </rdf:Description>
</rdf:RDF>

Universitätsbibliographie

Ja

Begutachtet

Ja