Quantum Entanglement and Thermal Reduced Density Matrices in Fermion and Spin Systems on Ladders

TL;DR

This paper explores how the reduced density matrix of gapped ladder systems resembles a thermal state, revealing universal entanglement properties and the role of the bulk gap as an effective temperature.

Contribution

It provides exact and approximate analyses of the reduced density matrix and entanglement entropy in fermionic and spin ladder systems, connecting entanglement to thermal states.

Findings

Reduced density matrix of gapped systems resembles a thermal state.

Entanglement entropy has a universal form dictated by conformal invariance.

Bulk gap acts as an effective temperature for long-wavelength modes.

Abstract

Numerical studies of the reduced density matrix of a gapped spin-1/2 Heisenberg antiferromagnet on a two-leg ladder find that it has the same form as the Gibbs density matrix of a gapless spin-1/2 Heisenberg antiferromagnetic chain at a finite temperature determined by the spin gap of the ladder. We investigate this interesting result by considering a model of free fermions on a two-leg ladder (gapped by the inter-chain tunneling operator) and in spin systems on a ladder with a gapped ground state using exact solutions and several controlled approximations. We calculate the reduced density matrix and the entanglement entropy for a leg of the ladder (i.e. cut made between the chains). In the fermionic system we find the exact form of the reduced density matrix for one of the chains and determine the entanglement spectrum explicitly. Here we find that in the weak tunneling limit of the ladder the entanglement entropy of one chain of the gapped ladder has a simple and universal form dictated by conformal invariance. In the case of the spin system, we consider the strong coupling limit by using perturbation theory and get the reduced density matrix by the Schmidt decomposition. The entanglement entropies of a general gapped system of two coupled conformal field theories (in 1+1 dimensions) is discussed using the replica trick and scaling arguments. We show that 1) for a system with a bulk gap the reduced density matrix has the form of a thermal density matrix, 2) the long-wavelength modes of one subsystem (a chain) of a gapped coupled system are always thermal, 3) the von Neumann entropy equals to the thermodynamic entropy of one chain, and 4) the bulk gap plays the role of effective temperature.