Entanglement Entropy of Free Fermions in Timelike Slices

Abstract

We define the entanglement entropy of free fermion quantum states in an arbitrary spacetime slice of a discrete set of points, and particularly investigate timelike (causal) slices. For 1D lattice free fermions with an energy bandwidth E0, we calculate the time-direction entanglement entropy SA in a time-direction slice of a set of times tn=nτ (1 n K) spanning a time length t on the same site. For zero temperature ground states, we find that SA shows volume law when ττ0=2π/E0; in contrast, SA 13 t when τ=τ0, and SA16 t when τ<τ0, resembling the Calabrese-Cardy formula for one flavor of nonchiral and chiral fermion, respectively. For finite temperature thermal states, the mutual information also saturates when τ<τ0. For non-eigenstates, volume law in t and signatures of the Lieb-Robinson bound velocity can be observed in SA. For generic spacetime slices with one point per site, the zero temperature entanglement entropy shows a clear transition from area law to volume law when the slice varies from spacelike to timelike.