Quantum Flutter: Signatures and Robustness

Michael Knap; Charles J. M. Mathy; Martin Ganahl; Mikhail B. Zvonarev; Eugene Demler

doi:10.1103/PhysRevLett.112.015302

Quantum Flutter: Signatures and Robustness

Michael Knap, Charles J. M. Mathy, Martin Ganahl, Mikhail B. Zvonarev, Eugene Demler

Institute of Theoretical and Computational Physics (5150)

Research output: Contribution to journal › Article › peer-review

Abstract

We investigate the motion of an impurity particle injected with finite velocity into an interacting one-dimensional quantum gas. Using large-scale numerical simulations based on matrix product states, we observe and quantitatively analyze long-lived oscillations of the impurity momentum around a nonzero saturation value, called quantum flutter. We show that the quantum flutter frequency is equal to the energy difference between two branches of collective excitations of the model. We propose an explanation of the finite saturation momentum of the impurity based on the properties of the edge of the excitation spectrum. Our results indicate that quantum flutter exists away from integrability and provide parameter regions in which it could be observed in experiments with ultracold atoms using currently available technology.

Original language	English
Article number	015302
Number of pages	5
Journal	Physical Review Letters
Volume	112
DOIs	https://doi.org/10.1103/PhysRevLett.112.015302
Publication status	Published - 2014

Fields of Expertise

Advanced Materials Science

Treatment code (Nähere Zuordnung)

Basic - Fundamental (Grundlagenforschung)
Theoretical

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10.1103/PhysRevLett.112.015302

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title = "Quantum Flutter: Signatures and Robustness",

abstract = "We investigate the motion of an impurity particle injected with finite velocity into an interacting one-dimensional quantum gas. Using large-scale numerical simulations based on matrix product states, we observe and quantitatively analyze long-lived oscillations of the impurity momentum around a nonzero saturation value, called quantum flutter. We show that the quantum flutter frequency is equal to the energy difference between two branches of collective excitations of the model. We propose an explanation of the finite saturation momentum of the impurity based on the properties of the edge of the excitation spectrum. Our results indicate that quantum flutter exists away from integrability and provide parameter regions in which it could be observed in experiments with ultracold atoms using currently available technology.",

author = "Michael Knap and Mathy, {Charles J. M.} and Martin Ganahl and Zvonarev, {Mikhail B.} and Eugene Demler",

year = "2014",

doi = "10.1103/PhysRevLett.112.015302",

language = "English",

volume = "112",

journal = "Physical Review Letters",

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publisher = "American Physical Society",

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AU - Mathy, Charles J. M.

AU - Ganahl, Martin

AU - Zvonarev, Mikhail B.

AU - Demler, Eugene

PY - 2014

Y1 - 2014

N2 - We investigate the motion of an impurity particle injected with finite velocity into an interacting one-dimensional quantum gas. Using large-scale numerical simulations based on matrix product states, we observe and quantitatively analyze long-lived oscillations of the impurity momentum around a nonzero saturation value, called quantum flutter. We show that the quantum flutter frequency is equal to the energy difference between two branches of collective excitations of the model. We propose an explanation of the finite saturation momentum of the impurity based on the properties of the edge of the excitation spectrum. Our results indicate that quantum flutter exists away from integrability and provide parameter regions in which it could be observed in experiments with ultracold atoms using currently available technology.

AB - We investigate the motion of an impurity particle injected with finite velocity into an interacting one-dimensional quantum gas. Using large-scale numerical simulations based on matrix product states, we observe and quantitatively analyze long-lived oscillations of the impurity momentum around a nonzero saturation value, called quantum flutter. We show that the quantum flutter frequency is equal to the energy difference between two branches of collective excitations of the model. We propose an explanation of the finite saturation momentum of the impurity based on the properties of the edge of the excitation spectrum. Our results indicate that quantum flutter exists away from integrability and provide parameter regions in which it could be observed in experiments with ultracold atoms using currently available technology.

UR - http://prl.aps.org

UR - http://prl.aps.org/abstract/PRL/v112/i1/e015302

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DO - 10.1103/PhysRevLett.112.015302

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VL - 112

JO - Physical Review Letters

JF - Physical Review Letters

M1 - 015302

ER -

Quantum Flutter: Signatures and Robustness

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