Area law and its violation: A microscopic inspection into the structure of entanglement and fluctuations

TL;DR

This paper introduces a microscopic contour-based approach to analyze the spatial structure of entanglement and fluctuations in quantum many-body systems, revealing different behaviors in free fermions and interacting bosons and exploring violations of the area law.

Contribution

It generalizes the concept of entanglement contour to quadratic lattice Hamiltonians and particle fluctuations, providing new insights into their spatial decay and relationship.

Findings

Entanglement contour decays away from the boundary in general.

In free fermions, entanglement and fluctuation contours decay similarly.

In interacting bosons, entanglement and fluctuation contours differ significantly.

Abstract

Quantum fluctuations of local quantities can be a direct signature of entanglement in an extended quantum many-body system. Hence they may serve as a theoretical (as well as an experimental) tool to detect the spatial properties of the entanglement entropy of a subsystem. In the ground state of quantum many-body systems, its scaling is typically linear in the boundary of the subsystem (area law). Here we propose a microscopic insight into the spatial structure of entanglement and fluctuations using the concept of \emph{contour}, recently introduced to decompose the bipartite entanglement entropy of lattice free fermions between two extended regions $A$ and $B$ into contributions from single sites in $A$. We generalize the notion of contour to the entanglement of any quadratic (bosonic or fermionic) lattice Hamiltonian, as well as to particle-number fluctuations. The entanglement and fluctuations contours are found to generally decay when moving away from the boundary between $A$ and $B$. We show that in the case of free fermions the decay of the entanglement contour follows closely that of the fluctuation contour. In the case of Bose-condensed interacting bosons, treated via the Bogoliubov and spin-wave approximations, such a link cannot be established -- fluctuation and entanglement contours are found to be radically different, as they lead to a logarithmically violated area law for fluctuations, and to a strict area law of entanglement. Analyzing in depth the role of the zero-energy Goldstone mode of spin-wave theory, and of the corresponding lowest-energy mode in the entanglement spectrum, we unveil a subtle interplay between the special contour and energy scaling of the latter, and universal additive logarithmic corrections to entanglement area law discussed extensively in the recent literature.