Single-site entanglement as a marker for quantum phase transitions at non-zero temperatures

TL;DR

This study demonstrates that single-site entanglement effectively signals quantum phase transitions in the two-dimensional Hubbard model at finite temperatures, providing a practical tool for experimental detection and characterization.

Contribution

It introduces the use of average single-site entanglement as a marker for quantum phase transitions at non-zero temperatures in lattice systems.

Findings

Single-site entanglement signals quantum phase transitions.

Entanglement correlates linearly with magnetic susceptibility.

Method applicable to various geometries and temperatures.

Abstract

Entanglement has been widely investigated in condensed matter systems since they are considered good candidates for developing quantum technologies. Additionally, entanglement is a powerful tool to explore quantum phase transitions in strongly correlated systems, with the von Neumann entropy being considered a proper measure of quantum entanglement for pure bipartite systems. For lattice systems, in particular, the single-site entanglement quantifies how much information about the quantum state of the remaining sites can be obtained by a measurement at a single site. Here, we use Quantum Monte Carlo calculations to obtain the average single-site entanglement for the two-dimensional Hubbard model in different geometries, probing the effects of varying temperature and interaction strength. We find that the average single-site entanglement signals the quantum phase transitions in such systems, allowing us to identify and characterize signatures of quantum phase transitions even at finite temperatures. We also analyze the relation between entanglement and magnetic susceptibility: in all the geometries considered, we find regimes in which the quantities are linearly connected. Our findings could then guide experiments to estimate entanglement via the susceptibility.