Test of Transitivity in Quantum Field theory using Rindler spacetime

Abstract

We consider a massless scalar field in Minkowski spacetime M in its vacuum state, and consider two Rindler wedges R1 and R2 in this space. R2 is shifted to the right of R1 by a distance . We therefore have R2⊂ R1 ⊂ M with the symbol ⊂ implying a quantum subsystem. We find the reduced state in R2 using two independent ways: a) by evaluation of the reduced state from vacuum state in M which yields a thermal density matrix, b) by first evaluating the reduced state in R1 from M yielding a thermal state in R1, and subsequently evaluate the reduced state in R2 in that order of sequence. In this article we attempt to address the question whether both these independent ways yield the same reduced state in R2. To that end, we devise a method which involves cleaving the Rindler wedge R1 into two domains such that they form a thermofield double. One of the domains aligns itself along the wedge R2 while the other is a diamond shaped construction between the boundaries of R1 and R2. We conclude that both these independent methods yield two different answers, and discuss the possible implications of our result in the context of quantum states outside a non-extremal black hole formed by collapsing matter.