Entanglement Entropy of Disjoint Regions in Excited States : An Operator Method

Abstract

We develop the computational method of entanglement entropy based on the idea that Trn is written as the expectation value of the local operator, where is a density matrix of the subsystem . We apply it to consider the mutual Renyi information I(n)(A,B)=S(n)A+S(n)B-S(n)A B of disjoint compact spatial regions A and B in the locally excited states defined by acting the local operators at A and B on the vacuum of a (d+1)-dimensional field theory, in the limit when the separation r between A and B is much greater than their sizes RA,B. For the general QFT which has a mass gap, we compute I(n)(A,B) explicitly and find that this result is interpreted in terms of an entangled state in quantum mechanics. For a free massless scalar field, we show that for some classes of excited states, I(n)(A,B)-I(n)(A,B)|r → ∞ =C(n)AB/rα (d-1) where α=1 or 2 which is determined by the property of the local operators under the transformation φ → -φ and α=2 for the vacuum state. We give a method to compute C(2)AB systematically.