Related papers: Finite-Temperature Simulations of Quantum Lattice Models with Stochastic Matrix Product States

Finite-Temperature Simulations of Quantum Lattice Models with Stochastic Matrix Product States

URL: http://arxiv.org/abs/2312.04420v1
Date: Thu, 7 Dec 2023 16:44:08 GMT
Title: Finite-Temperature Simulations of Quantum Lattice Models with Stochastic Matrix Product States
Authors: Jianxin Gao, Yuan Gao, Qiaoyi Li, Wei Li
Abstract summary: We develop a matrix product state (stoMPS) approach that combines the MPS technique and Monte Carlo samplings. We benchmark the methods on small system sizes and compare the results to those obtained with minimally entangled typical thermal states. Our results showcase the accuracy and effectiveness of networks in finite-temperature simulations.
Score: 7.376159230492167
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: In this work, we develop a stochastic matrix product state (stoMPS) approach that combines the MPS technique and Monte Carlo samplings and can be applied to simulate quantum lattice models down to low temperature. In particular, we exploit a procedure to unbiasedly sample the local tensors in the matrix product states, which has one physical index of dimension $d$ and two geometric indices of dimension $D$, and find the results can be continuously improved by enlarging $D$. We benchmark the methods on small system sizes and then compare the results to those obtained with minimally entangled typical thermal states, finding that stoMPS has overall better performance with finite $D$. We further exploit the MPS sampling to simulate long spin chains, as well as the triangular and square lattices with cylinder circumference $W$ up to 4. Our results showcase the accuracy and effectiveness of stochastic tensor networks in finite-temperature simulations.

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