Fluctuations and non-Hermiticity in the stochastic approach to quantum spins

S. E. Begg; A. G. Green; M. J. Bhaseen

doi:10.1088/1751-8121/abbf87

Fluctuations and non-Hermiticity in the stochastic approach to quantum spins

S. E. Begg^*, A. G. Green, M. J. Bhaseen

^*Corresponding author for this work

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

4 Citations (Scopus)

Abstract

We investigate the non-equilibrium dynamics of isolated quantum spin systems via an exact mapping to classical stochastic differential equations. We show that one can address significantly larger system sizes than recently obtained, including two-dimensional systems with up to 49 spins. We demonstrate that the results for physical observables are in excellent agreement with exact results and alternative numerical techniques where available. We further develop a hybrid stochastic approach involving matrix product states. In the presence of finite numerical sampling, we show that the non-Hermitian character of the stochastic representation leads to the growth of the norm of the time-evolving quantum state and to departures for physical observables at late times. We demonstrate approaches that correct for this and discuss the prospects for further development.

Original language	English
Article number	50LT02
Journal	Journal of Physics A: Mathematical and Theoretical
Volume	53
Issue number	50
DOIs	https://doi.org/10.1088/1751-8121/abbf87
Publication status	Published - 18 Nov 2020

Keywords

nonequilibrium
quantum quench
quantum spins
stochastic processes

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10.1088/1751-8121/abbf87

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abstract = "We investigate the non-equilibrium dynamics of isolated quantum spin systems via an exact mapping to classical stochastic differential equations. We show that one can address significantly larger system sizes than recently obtained, including two-dimensional systems with up to 49 spins. We demonstrate that the results for physical observables are in excellent agreement with exact results and alternative numerical techniques where available. We further develop a hybrid stochastic approach involving matrix product states. In the presence of finite numerical sampling, we show that the non-Hermitian character of the stochastic representation leads to the growth of the norm of the time-evolving quantum state and to departures for physical observables at late times. We demonstrate approaches that correct for this and discuss the prospects for further development.",

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T1 - Fluctuations and non-Hermiticity in the stochastic approach to quantum spins

AU - Begg, S. E.

AU - Green, A. G.

AU - Bhaseen, M. J.

PY - 2020/11/18

Y1 - 2020/11/18

N2 - We investigate the non-equilibrium dynamics of isolated quantum spin systems via an exact mapping to classical stochastic differential equations. We show that one can address significantly larger system sizes than recently obtained, including two-dimensional systems with up to 49 spins. We demonstrate that the results for physical observables are in excellent agreement with exact results and alternative numerical techniques where available. We further develop a hybrid stochastic approach involving matrix product states. In the presence of finite numerical sampling, we show that the non-Hermitian character of the stochastic representation leads to the growth of the norm of the time-evolving quantum state and to departures for physical observables at late times. We demonstrate approaches that correct for this and discuss the prospects for further development.

AB - We investigate the non-equilibrium dynamics of isolated quantum spin systems via an exact mapping to classical stochastic differential equations. We show that one can address significantly larger system sizes than recently obtained, including two-dimensional systems with up to 49 spins. We demonstrate that the results for physical observables are in excellent agreement with exact results and alternative numerical techniques where available. We further develop a hybrid stochastic approach involving matrix product states. In the presence of finite numerical sampling, we show that the non-Hermitian character of the stochastic representation leads to the growth of the norm of the time-evolving quantum state and to departures for physical observables at late times. We demonstrate approaches that correct for this and discuss the prospects for further development.

KW - nonequilibrium

KW - quantum quench

KW - quantum spins

KW - stochastic processes

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DO - 10.1088/1751-8121/abbf87

M3 - Article

AN - SCOPUS:85097315963

SN - 1751-8113

VL - 53

JO - Journal of Physics A: Mathematical and Theoretical

JF - Journal of Physics A: Mathematical and Theoretical

IS - 50

M1 - 50LT02

ER -

Fluctuations and non-Hermiticity in the stochastic approach to quantum spins

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Keywords

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