Ground State Entanglement in One Dimensional Translationally Invariant Quantum Systems

TL;DR

This paper constructs one-dimensional translationally-invariant Hamiltonians with ground states exhibiting polynomially scaling entanglement entropy, challenging previous bounds and deepening understanding of entanglement in quantum many-body systems.

Contribution

It introduces a family of translationally-invariant Hamiltonians with ground states that have entanglement entropy scaling polynomially with 1/Delta, surpassing previous logarithmic bounds.

Findings

Ground states can have entanglement entropy scaling polynomially with 1/Delta.

Constructed Hamiltonians with spectral gap Omega(1/poly(n)).

High entanglement persists in ground states despite translational invariance.

Abstract

We examine whether it is possible for one-dimensional translationally-invariant Hamiltonians to have ground states with a high degree of entanglement. We present a family of translationally invariant Hamiltonians {H_n} for the infinite chain. The spectral gap of H_n is Omega(1/poly(n)). Moreover, for any state in the ground space of H_n and any m, there are regions of size m with entanglement entropy Omega(min{m,n}). A similar construction yields translationally-invariant Hamiltonians for finite chains that have unique ground states exhibiting high entanglement. The area law proven by Hastings gives a constant upper bound on the entanglement entropy for 1D ground states that is independent of the size of the region but exponentially dependent on 1/Delta, where Delta is the spectral gap. This paper provides a lower bound, showing a family of Hamiltonians for which the entanglement entropy scales polynomially with 1/Delta. Previously, the best known such bound was logarithmic in 1/Delta.