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Bibliographic Details
Main Authors: Gentinetta, Gian, Metz, Friederike, Kirby, William, Carleo, Giuseppe
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.25394
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author Gentinetta, Gian
Metz, Friederike
Kirby, William
Carleo, Giuseppe
author_facet Gentinetta, Gian
Metz, Friederike
Kirby, William
Carleo, Giuseppe
contents The computation of thermal properties of quantum many-body systems is a central challenge in our understanding of quantum mechanics. We introduce the Quantum Finite Temperature Lanczos Method (QFTLM), which extends the finite-temperature Lanczos method to quantum computers by combining real-time quantum Krylov methods with efficient preparation of typical states for trace estimation. This approach enables the computation of thermal expectation values while avoiding the exponential scaling inherent to classical exact simulation techniques. Numerical experiments on the transverse-field Ising model show that QFTLM can reproduce thermal observables over a wide temperature range. We further analyze the influence of Krylov dimension, number of trace-estimator states, and Trotter error, and show that suitable regularization is essential for robustness in noisy settings. These results establish QFTLM as a promising framework for finite-temperature quantum simulation.
format Preprint
id arxiv_https___arxiv_org_abs_2603_25394
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Quantum Finite Temperature Lanczos Method
Gentinetta, Gian
Metz, Friederike
Kirby, William
Carleo, Giuseppe
Quantum Physics
The computation of thermal properties of quantum many-body systems is a central challenge in our understanding of quantum mechanics. We introduce the Quantum Finite Temperature Lanczos Method (QFTLM), which extends the finite-temperature Lanczos method to quantum computers by combining real-time quantum Krylov methods with efficient preparation of typical states for trace estimation. This approach enables the computation of thermal expectation values while avoiding the exponential scaling inherent to classical exact simulation techniques. Numerical experiments on the transverse-field Ising model show that QFTLM can reproduce thermal observables over a wide temperature range. We further analyze the influence of Krylov dimension, number of trace-estimator states, and Trotter error, and show that suitable regularization is essential for robustness in noisy settings. These results establish QFTLM as a promising framework for finite-temperature quantum simulation.
title Quantum Finite Temperature Lanczos Method
topic Quantum Physics
url https://arxiv.org/abs/2603.25394