Insights into Phase Transitions and Entanglement from Density Functional Theory

TL;DR

This paper demonstrates how density functional theory can be used to analyze phase transitions and entanglement in quantum many-body systems at finite temperatures, revealing universal relationships and nonanalytic behaviors at critical points.

Contribution

It introduces a novel approach linking density functional theory to phase transitions and entanglement, expressing physical observables as functionals of free energy derivatives.

Findings

Physical observables are universal functionals of free energy derivatives.

Phase transitions cause nonanalytic behavior in observables and entanglement measures.

Model demonstration confirms the theoretical insights.

Abstract

Density functional theory has made great success in solid state physics, quantum chemistry and in computational material sciences. In this work we show that density functional theory could shed light on phase transitions and entanglement at finite temperatures. Specifically, we show that the equilibrium state of an interacting quantum many-body system which is in thermal equilibrium with a heat bath at a fixed temperature is a universal functional of the first derivatives of the free energy with respect to temperature and other control parameters respectively. This insight from density functional theory enables us to express the average value of any physical observable and any entanglement measure as a universal functional of the first derivatives of the free energy with respect to temperature and other control parameters. Since phase transitions are marked by the nonanalytic behavior of free energy with respect to control parameters, the physical quantities and entanglement measures may present nonanalytic behavior at critical point inherited from their dependence on the first derivative of free energy. We use an experimentally realizable model to demonstrate the idea. These results give new insights for phase transitions and provide new profound connections between entanglement and phase transition in interacting quantum many-body physics.