Parametric Instabilities of Interacting Bosons in Periodically Driven 1D Optical Lattices

Parametric Instabilities of Interacting Bosons in Periodically Driven 1D Optical Lattices

Periodically driven quantum systems are currently explored in view of realizing novel many-body phases of matter. This approach is particularly promising in gases of ultracold atoms, where sophisticated shaking protocols can be realized and interparticle interactions are well controlled. The combina...

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Main Authors: K. Wintersperger, M. Bukov, J. Näger, S. Lellouch, E. Demler, U. Schneider, I. Bloch, N. Goldman, M. Aidelsburger
Format: Article
Language:English
Published: American Physical Society 2020-02-01
Series:Physical Review X
Online Access:http://doi.org/10.1103/PhysRevX.10.011030
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spelling doaj-94e6e1c5dad84e4ca545bf456145fcd82020-11-25T03:15:07ZengAmerican Physical SocietyPhysical Review X2160-33082020-02-0110101103010.1103/PhysRevX.10.011030Parametric Instabilities of Interacting Bosons in Periodically Driven 1D Optical LatticesK. WinterspergerM. BukovJ. NägerS. LellouchE. DemlerU. SchneiderI. BlochN. GoldmanM. AidelsburgerPeriodically driven quantum systems are currently explored in view of realizing novel many-body phases of matter. This approach is particularly promising in gases of ultracold atoms, where sophisticated shaking protocols can be realized and interparticle interactions are well controlled. The combination of interactions and time-periodic driving, however, often leads to uncontrollable heating and instabilities, potentially preventing practical applications of Floquet engineering in large many-body quantum systems. In this work, we experimentally identify the existence of parametric instabilities in weakly interacting Bose-Einstein condensates in strongly driven optical lattices through momentum-resolved measurements, in line with theoretical predictions. Parametric instabilities can trigger the destruction of weakly interacting Bose-Einstein condensates through the rapid growth of collective excitations, in particular in systems with weak harmonic confinement transverse to the lattice axis. Understanding the onset of parametric instabilities in driven quantum matter is crucial for determining optimal conditions for the engineering of modulation-induced many-body systems.http://doi.org/10.1103/PhysRevX.10.011030
collection DOAJ
language English
format Article
sources DOAJ
author K. Wintersperger
M. Bukov
J. Näger
S. Lellouch
E. Demler
U. Schneider
I. Bloch
N. Goldman
M. Aidelsburger
spellingShingle K. Wintersperger
M. Bukov
J. Näger
S. Lellouch
E. Demler
U. Schneider
I. Bloch
N. Goldman
M. Aidelsburger
Parametric Instabilities of Interacting Bosons in Periodically Driven 1D Optical Lattices
Physical Review X
author_facet K. Wintersperger
M. Bukov
J. Näger
S. Lellouch
E. Demler
U. Schneider
I. Bloch
N. Goldman
M. Aidelsburger
author_sort K. Wintersperger
title Parametric Instabilities of Interacting Bosons in Periodically Driven 1D Optical Lattices
title_short Parametric Instabilities of Interacting Bosons in Periodically Driven 1D Optical Lattices
title_full Parametric Instabilities of Interacting Bosons in Periodically Driven 1D Optical Lattices
title_fullStr Parametric Instabilities of Interacting Bosons in Periodically Driven 1D Optical Lattices
title_full_unstemmed Parametric Instabilities of Interacting Bosons in Periodically Driven 1D Optical Lattices
title_sort parametric instabilities of interacting bosons in periodically driven 1d optical lattices
publisher American Physical Society
series Physical Review X
issn 2160-3308
publishDate 2020-02-01
description Periodically driven quantum systems are currently explored in view of realizing novel many-body phases of matter. This approach is particularly promising in gases of ultracold atoms, where sophisticated shaking protocols can be realized and interparticle interactions are well controlled. The combination of interactions and time-periodic driving, however, often leads to uncontrollable heating and instabilities, potentially preventing practical applications of Floquet engineering in large many-body quantum systems. In this work, we experimentally identify the existence of parametric instabilities in weakly interacting Bose-Einstein condensates in strongly driven optical lattices through momentum-resolved measurements, in line with theoretical predictions. Parametric instabilities can trigger the destruction of weakly interacting Bose-Einstein condensates through the rapid growth of collective excitations, in particular in systems with weak harmonic confinement transverse to the lattice axis. Understanding the onset of parametric instabilities in driven quantum matter is crucial for determining optimal conditions for the engineering of modulation-induced many-body systems.
url http://doi.org/10.1103/PhysRevX.10.011030
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