Learning quantum Gibbs states locally and efficiently
Abstract
Learning the Hamiltonian underlying a quantum many-body system in thermal equilibrium is a fundamental task in quantum learning theory and experimental sciences. To learn the Gibbs state of local Hamiltonians at any inverse temperature , the state-of-the-art provable algorithms fall short of the optimal sample and computational complexity, in sharp contrast with the locality and simplicity in the classical cases. In this work, we present a learning algorithm that learns each local term of a -qubit -dimensional Hamiltonian to an additive error with sample complexity . The protocol uses parallelizable local quantum measurements that act within bounded regions of the lattice and near-linear-time classical post-processing. Thus, our complexity is near optimal with respect to and is polynomially tight with respect to . We also give a learning algorithm for Hamiltonians with bounded interaction degree with sample and time complexities of similar scaling on but worse on . At the heart of our algorithm is the interplay between locality, the Kubo-Martin-Schwinger condition, and the operator Fourier transform at arbitrary temperatures.
Cite
@article{arxiv.2504.02706,
title = {Learning quantum Gibbs states locally and efficiently},
author = {Chi-Fang Chen and Anurag Anshu and Quynh T. Nguyen},
journal= {arXiv preprint arXiv:2504.02706},
year = {2025}
}
Comments
35 pages, 2 figures