Return probability of N fermions released from a 1D confining potential

P. L. Krapivsky; J. M. Luck; K. Mallick

doi:10.1088/1742-5468/aaf8a2

Return probability of N fermions released from a 1D confining potential

P. L. Krapivsky, J. M. Luck, K. Mallick

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

Abstract

We consider N non-interacting fermions prepared in the ground state of a 1D confining potential and submitted to an instantaneous quench consisting in releasing the trapping potential. We show that the quantum return probability of finding the fermions in their initial state at a later time falls off as a power law in the long-time regime, with a universal exponent depending only on N and on whether the free fermions expand over the full line or over a half-line. In both geometries, the amplitudes of this power-law decay are expressed in terms of finite determinants of moments of the one-body bound-state wavefunctions in the potential. These amplitudes are worked out explicitly for the harmonic and square-well potentials. At large fermion numbers they obey scaling laws involving the Fermi energy of the initial state. The use of the Selberg-Mehta integrals stemming from random matrix theory has been instrumental in the derivation of these results.

Original language	English
Article number	023103
Journal	Journal of Statistical Mechanics: Theory and Experiment
Volume	2019
Issue number	2
DOIs	https://doi.org/10.1088/1742-5468/aaf8a2
Publication status	Published - 14 Feb 2019
Externally published	Yes

Keywords

mesoscopic systems
quantum transport in one-dimension

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10.1088/1742-5468/aaf8a2

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title = "Return probability of N fermions released from a 1D confining potential",

abstract = "We consider N non-interacting fermions prepared in the ground state of a 1D confining potential and submitted to an instantaneous quench consisting in releasing the trapping potential. We show that the quantum return probability of finding the fermions in their initial state at a later time falls off as a power law in the long-time regime, with a universal exponent depending only on N and on whether the free fermions expand over the full line or over a half-line. In both geometries, the amplitudes of this power-law decay are expressed in terms of finite determinants of moments of the one-body bound-state wavefunctions in the potential. These amplitudes are worked out explicitly for the harmonic and square-well potentials. At large fermion numbers they obey scaling laws involving the Fermi energy of the initial state. The use of the Selberg-Mehta integrals stemming from random matrix theory has been instrumental in the derivation of these results.",

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T1 - Return probability of N fermions released from a 1D confining potential

AU - Krapivsky, P. L.

AU - Luck, J. M.

AU - Mallick, K.

PY - 2019/2/14

Y1 - 2019/2/14

N2 - We consider N non-interacting fermions prepared in the ground state of a 1D confining potential and submitted to an instantaneous quench consisting in releasing the trapping potential. We show that the quantum return probability of finding the fermions in their initial state at a later time falls off as a power law in the long-time regime, with a universal exponent depending only on N and on whether the free fermions expand over the full line or over a half-line. In both geometries, the amplitudes of this power-law decay are expressed in terms of finite determinants of moments of the one-body bound-state wavefunctions in the potential. These amplitudes are worked out explicitly for the harmonic and square-well potentials. At large fermion numbers they obey scaling laws involving the Fermi energy of the initial state. The use of the Selberg-Mehta integrals stemming from random matrix theory has been instrumental in the derivation of these results.

AB - We consider N non-interacting fermions prepared in the ground state of a 1D confining potential and submitted to an instantaneous quench consisting in releasing the trapping potential. We show that the quantum return probability of finding the fermions in their initial state at a later time falls off as a power law in the long-time regime, with a universal exponent depending only on N and on whether the free fermions expand over the full line or over a half-line. In both geometries, the amplitudes of this power-law decay are expressed in terms of finite determinants of moments of the one-body bound-state wavefunctions in the potential. These amplitudes are worked out explicitly for the harmonic and square-well potentials. At large fermion numbers they obey scaling laws involving the Fermi energy of the initial state. The use of the Selberg-Mehta integrals stemming from random matrix theory has been instrumental in the derivation of these results.

KW - mesoscopic systems

KW - quantum transport in one-dimension

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DO - 10.1088/1742-5468/aaf8a2

M3 - Article

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SN - 1742-5468

VL - 2019

JO - Journal of Statistical Mechanics: Theory and Experiment

JF - Journal of Statistical Mechanics: Theory and Experiment

IS - 2

M1 - 023103

ER -

Return probability of N fermions released from a 1D confining potential

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