Long-Lived Interacting Phases of Matter Protected by Multiple Time-Translation Symmetries in Quasiperiodically Driven Systems

Long-Lived Interacting Phases of Matter Protected by Multiple Time-Translation Symmetries in Quasiperiodically Driven Systems

We show how a large family of interacting nonequilibrium phases of matter can arise from the presence of multiple time-translation symmetries, which occur by quasiperiodically driving an isolated, quantum many-body system with two or more incommensurate frequencies. These phases are fundamentally di...

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Main Authors: Dominic V. Else, Wen Wei Ho, Philipp T. Dumitrescu
Format: Article
Language:English
Published: American Physical Society 2020-05-01
Series:Physical Review X
Online Access:http://doi.org/10.1103/PhysRevX.10.021032
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spelling doaj-44cfedba6b0a4264b6c2be6827eb02b52020-11-25T02:41:49ZengAmerican Physical SocietyPhysical Review X2160-33082020-05-0110202103210.1103/PhysRevX.10.021032Long-Lived Interacting Phases of Matter Protected by Multiple Time-Translation Symmetries in Quasiperiodically Driven SystemsDominic V. ElseWen Wei HoPhilipp T. DumitrescuWe show how a large family of interacting nonequilibrium phases of matter can arise from the presence of multiple time-translation symmetries, which occur by quasiperiodically driving an isolated, quantum many-body system with two or more incommensurate frequencies. These phases are fundamentally different from those realizable in time-independent or periodically driven (Floquet) settings. Focusing on high-frequency drives with smooth time dependence, we rigorously establish general conditions for which these phases are stable in a parametrically long-lived “preheating” regime. We develop a formalism to analyze the effect of the multiple time-translation symmetries on the dynamics of the system, which we use to classify and construct explicit examples of the emergent phases. In particular, we discuss time quasicrystals which spontaneously break the time-translation symmetries, as well as time-translation symmetry-protected topological phases.http://doi.org/10.1103/PhysRevX.10.021032
collection DOAJ
language English
format Article
sources DOAJ
author Dominic V. Else
Wen Wei Ho
Philipp T. Dumitrescu
spellingShingle Dominic V. Else
Wen Wei Ho
Philipp T. Dumitrescu
Long-Lived Interacting Phases of Matter Protected by Multiple Time-Translation Symmetries in Quasiperiodically Driven Systems
Physical Review X
author_facet Dominic V. Else
Wen Wei Ho
Philipp T. Dumitrescu
author_sort Dominic V. Else
title Long-Lived Interacting Phases of Matter Protected by Multiple Time-Translation Symmetries in Quasiperiodically Driven Systems
title_short Long-Lived Interacting Phases of Matter Protected by Multiple Time-Translation Symmetries in Quasiperiodically Driven Systems
title_full Long-Lived Interacting Phases of Matter Protected by Multiple Time-Translation Symmetries in Quasiperiodically Driven Systems
title_fullStr Long-Lived Interacting Phases of Matter Protected by Multiple Time-Translation Symmetries in Quasiperiodically Driven Systems
title_full_unstemmed Long-Lived Interacting Phases of Matter Protected by Multiple Time-Translation Symmetries in Quasiperiodically Driven Systems
title_sort long-lived interacting phases of matter protected by multiple time-translation symmetries in quasiperiodically driven systems
publisher American Physical Society
series Physical Review X
issn 2160-3308
publishDate 2020-05-01
description We show how a large family of interacting nonequilibrium phases of matter can arise from the presence of multiple time-translation symmetries, which occur by quasiperiodically driving an isolated, quantum many-body system with two or more incommensurate frequencies. These phases are fundamentally different from those realizable in time-independent or periodically driven (Floquet) settings. Focusing on high-frequency drives with smooth time dependence, we rigorously establish general conditions for which these phases are stable in a parametrically long-lived “preheating” regime. We develop a formalism to analyze the effect of the multiple time-translation symmetries on the dynamics of the system, which we use to classify and construct explicit examples of the emergent phases. In particular, we discuss time quasicrystals which spontaneously break the time-translation symmetries, as well as time-translation symmetry-protected topological phases.
url http://doi.org/10.1103/PhysRevX.10.021032
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AT wenweiho longlivedinteractingphasesofmatterprotectedbymultipletimetranslationsymmetriesinquasiperiodicallydrivensystems
AT philipptdumitrescu longlivedinteractingphasesofmatterprotectedbymultipletimetranslationsymmetriesinquasiperiodicallydrivensystems
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