Polynomial-time Classical Simulation for One-dimensional Quantum Gibbs States
Abstract
This paper discusses a classical simulation to compute the partition function (or free energy) of generic one-dimensional quantum many-body systems. Many numerical methods have previously been developed to approximately solve one-dimensional quantum systems. However, there exists no exact proof that arbitrary one-dimensional quantum Gibbs states can be efficiently solved by a classical computer. Therefore, the aim of this paper is to prove this with the clustering properties for arbitrary finite temperatures . We explicitly show an efficient algorithm that approximates the partition function up to an error with a computational cost that scales as , where the degree of the polynomial depends on as . Extending the analysis to higher dimensions at high temperatures, we obtain a weaker result for the computational cost n\cdot (1/\epsilon)^{\log^{D-1} (1/\epsilon)}, where is the lattice dimension.
Cite
@article{arxiv.1807.08424,
title = {Polynomial-time Classical Simulation for One-dimensional Quantum Gibbs States},
author = {Tomotaka Kuwahara and Keiji Saito},
journal= {arXiv preprint arXiv:1807.08424},
year = {2018}
}
Comments
11 pages, 4 figures