Variational Monte Carlo simulation with tensor networks of a pure Z 3 gauge theory in ( 2 + 1 ) D

Abstract

Variational minimization of tensor network states enables the exploration of low energy states of lattice gauge theories. However, the exact numerical evaluation of high-dimensional tensor network states remains challenging. By combining gauged Gaussian projected entangled pair states with a variational Monte Carlo procedure, we are able to efficiently compute ground state energies. We demonstrate the method for a pure gauge Kogut-Susskind Hamiltonian with a $\mathbb{Z}_3$ gauge field in two spatial dimensions. The method provides an inherent way to increase the number of variational parameters and can be readily extended to systems with physical fermions.