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Autori principali: Bhat, Junaid Majeed, Znidaric, Marko
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2501.13560
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author Bhat, Junaid Majeed
Znidaric, Marko
author_facet Bhat, Junaid Majeed
Znidaric, Marko
contents Solving for the time evolution of a many particle system whose dynamics is governed by Lindblad equation is hard. We extend the use of the transfer matrix approach to a class of Lindblad equations that admit a closed hierarchy of two point correlators. An example that we treat is the XX spin chain, i.e., free fermions, subject to the local on-site dephasing, but can be extended to other Hermitian dissipators, e.g., non-local dephasing. We find a simple expression of the Green's function in the Laplace domain. The method can be used to get analytical results in the thermodynamic limit, for instance, to get the evolution of the magnetization density and to explicitly see the crossover between ballistic and diffusive behavior, or to show that the correlations between operators at distance $l$ decay with time as $1/t^{\lceil l/2 \rceil+1/2}$. It also provides a fast numerical method to determine the evolution of the density with a complexity scaling with the system size more favorably than in previous methods, easily allowing one to study systems with $\sim 10^6$ spins.
format Preprint
id arxiv_https___arxiv_org_abs_2501_13560
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Transfer matrix approach to quantum systems subject to certain Lindblad evolution
Bhat, Junaid Majeed
Znidaric, Marko
Quantum Physics
Mesoscale and Nanoscale Physics
Statistical Mechanics
Solving for the time evolution of a many particle system whose dynamics is governed by Lindblad equation is hard. We extend the use of the transfer matrix approach to a class of Lindblad equations that admit a closed hierarchy of two point correlators. An example that we treat is the XX spin chain, i.e., free fermions, subject to the local on-site dephasing, but can be extended to other Hermitian dissipators, e.g., non-local dephasing. We find a simple expression of the Green's function in the Laplace domain. The method can be used to get analytical results in the thermodynamic limit, for instance, to get the evolution of the magnetization density and to explicitly see the crossover between ballistic and diffusive behavior, or to show that the correlations between operators at distance $l$ decay with time as $1/t^{\lceil l/2 \rceil+1/2}$. It also provides a fast numerical method to determine the evolution of the density with a complexity scaling with the system size more favorably than in previous methods, easily allowing one to study systems with $\sim 10^6$ spins.
title Transfer matrix approach to quantum systems subject to certain Lindblad evolution
topic Quantum Physics
Mesoscale and Nanoscale Physics
Statistical Mechanics
url https://arxiv.org/abs/2501.13560