An exactly solvable model for the integrability-chaos transition in rough quantum billiards

Maxim Olshanii; Kurt Jacobs; Marcos Rigol; Vanja Dunjko; Harry Kennard; Vladimir A. Yurovsky

doi:10.1038/ncomms1653

An exactly solvable model for the integrability-chaos transition in rough quantum billiards

Maxim Olshanii, Kurt Jacobs, Marcos Rigol, Vanja Dunjko, Harry Kennard, Vladimir A. Yurovsky

School of Chemistry

Tel Aviv University

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

Abstract

A central question of dynamics, largely open in the quantum case, is to what extent it erases a system's memory of its initial properties. Here we present a simple statistically solvable quantum model describing this memory loss across an integrability-chaos transition under a perturbation obeying no selection rules. From the perspective of quantum localization-delocalization on the lattice of quantum numbers, we are dealing with a situation where every lattice site is coupled to every other site with the same strength, on average. The model also rigorously justifies a similar set of relationships, recently proposed in the context of two short-range-interacting ultracold atoms in a harmonic waveguide. Application of our model to an ensemble of uncorrelated impurities on a rectangular lattice gives good agreement with ab initio numerics.

Original language	English
Article number	641
Journal	Nature Communications
Volume	3
DOIs	https://doi.org/10.1038/ncomms1653
State	Published - 2012

All Science Journal Classification (ASJC) codes

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General Physics and Astronomy

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10.1038/ncomms1653

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title = "An exactly solvable model for the integrability-chaos transition in rough quantum billiards",

abstract = "A central question of dynamics, largely open in the quantum case, is to what extent it erases a system's memory of its initial properties. Here we present a simple statistically solvable quantum model describing this memory loss across an integrability-chaos transition under a perturbation obeying no selection rules. From the perspective of quantum localization-delocalization on the lattice of quantum numbers, we are dealing with a situation where every lattice site is coupled to every other site with the same strength, on average. The model also rigorously justifies a similar set of relationships, recently proposed in the context of two short-range-interacting ultracold atoms in a harmonic waveguide. Application of our model to an ensemble of uncorrelated impurities on a rectangular lattice gives good agreement with ab initio numerics.",

author = "Maxim Olshanii and Kurt Jacobs and Marcos Rigol and Vanja Dunjko and Harry Kennard and Yurovsky, {Vladimir A.}",

note = "Funding Information: We. are grateful to F. Werner and D. Cohen for enlightening discussions on the subject. Supported by the Office of Naval Research grant N00014-09-1-0502 (M.O. and V.D.) and the National Science Foundation grants PHY-1019197 (M.O. and V.D.) and PHY-0902906 (K.J.).",

year = "2012",

doi = "10.1038/ncomms1653",

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journal = "Nature Communications",

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T1 - An exactly solvable model for the integrability-chaos transition in rough quantum billiards

AU - Olshanii, Maxim

AU - Jacobs, Kurt

AU - Rigol, Marcos

AU - Dunjko, Vanja

AU - Kennard, Harry

AU - Yurovsky, Vladimir A.

N1 - Funding Information: We. are grateful to F. Werner and D. Cohen for enlightening discussions on the subject. Supported by the Office of Naval Research grant N00014-09-1-0502 (M.O. and V.D.) and the National Science Foundation grants PHY-1019197 (M.O. and V.D.) and PHY-0902906 (K.J.).

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Y1 - 2012

N2 - A central question of dynamics, largely open in the quantum case, is to what extent it erases a system's memory of its initial properties. Here we present a simple statistically solvable quantum model describing this memory loss across an integrability-chaos transition under a perturbation obeying no selection rules. From the perspective of quantum localization-delocalization on the lattice of quantum numbers, we are dealing with a situation where every lattice site is coupled to every other site with the same strength, on average. The model also rigorously justifies a similar set of relationships, recently proposed in the context of two short-range-interacting ultracold atoms in a harmonic waveguide. Application of our model to an ensemble of uncorrelated impurities on a rectangular lattice gives good agreement with ab initio numerics.

AB - A central question of dynamics, largely open in the quantum case, is to what extent it erases a system's memory of its initial properties. Here we present a simple statistically solvable quantum model describing this memory loss across an integrability-chaos transition under a perturbation obeying no selection rules. From the perspective of quantum localization-delocalization on the lattice of quantum numbers, we are dealing with a situation where every lattice site is coupled to every other site with the same strength, on average. The model also rigorously justifies a similar set of relationships, recently proposed in the context of two short-range-interacting ultracold atoms in a harmonic waveguide. Application of our model to an ensemble of uncorrelated impurities on a rectangular lattice gives good agreement with ab initio numerics.

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U2 - 10.1038/ncomms1653

DO - 10.1038/ncomms1653

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JO - Nature Communications

JF - Nature Communications

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ER -

An exactly solvable model for the integrability-chaos transition in rough quantum billiards

Abstract

All Science Journal Classification (ASJC) codes

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