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Main Authors: Vilkoviskiy, Ilya, Matirko, Kirill
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.13883
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author Vilkoviskiy, Ilya
Matirko, Kirill
author_facet Vilkoviskiy, Ilya
Matirko, Kirill
contents One possible approach to studying non-equilibrium dynamics is the so-called influence matrix (IM) formalism. The influence matrix can be viewed as a quantum state that encodes complete information about the non-equilibrium dynamics of a boundary degree of freedom. It has been shown that the IM is the unique stationary point of the temporal transfer matrix. This transfer matrix, however, is non-diagonalizable and exhibits a non-trivial Jordan block structure. In this article, we demonstrate that, in the case of an integrable XXZ spin chain, the temporal transfer matrix itself is integrable and can be embedded into a family of commuting operators. We further provide the exact expression for the IM as a particular limit of a Bethe wavefunction, with the corresponding Bethe roots given explicitly. We also focus on the special case of the free-fermionic XX chain. In this setting, we uncover additional local integrals of motion, which enable us to analyze the dimensions and structure of the Jordan blocks, as well as the locality properties of the IM. Moreover, we construct a basis of quasi-local creation operators that generate the IM from the vacuum state.
format Preprint
id arxiv_https___arxiv_org_abs_2508_13883
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Properties of the temporal transfer matrix in integrable Floquet circuits
Vilkoviskiy, Ilya
Matirko, Kirill
Mathematical Physics
Quantum Physics
One possible approach to studying non-equilibrium dynamics is the so-called influence matrix (IM) formalism. The influence matrix can be viewed as a quantum state that encodes complete information about the non-equilibrium dynamics of a boundary degree of freedom. It has been shown that the IM is the unique stationary point of the temporal transfer matrix. This transfer matrix, however, is non-diagonalizable and exhibits a non-trivial Jordan block structure. In this article, we demonstrate that, in the case of an integrable XXZ spin chain, the temporal transfer matrix itself is integrable and can be embedded into a family of commuting operators. We further provide the exact expression for the IM as a particular limit of a Bethe wavefunction, with the corresponding Bethe roots given explicitly. We also focus on the special case of the free-fermionic XX chain. In this setting, we uncover additional local integrals of motion, which enable us to analyze the dimensions and structure of the Jordan blocks, as well as the locality properties of the IM. Moreover, we construct a basis of quasi-local creation operators that generate the IM from the vacuum state.
title Properties of the temporal transfer matrix in integrable Floquet circuits
topic Mathematical Physics
Quantum Physics
url https://arxiv.org/abs/2508.13883