Quantum out-states holographically induced by asymptotic flatness: Invariance under spacetime symmetries, energy positivity and Hadamard property

Abstract

This paper continues the analysis of the quantum states determined by the universal asymptotic structure of four-dimensional asymptotically flat vacuum spacetimes at null infinity M. It is now focused on the quantum state lambdaM, of a massles conformally coupled scalar field phi propagating in M. lambdaM is ``holographically'' induced in the bulk by the universal BMS-invariant state lambda at infinity scri of M. It is done by means of the correspondence between observables in the bulk and those on the boundary at null infinity discussed in previous papers. The induction is possible when some requirements are fulfilled, in particular the spacetime M and the associated unphysical one are globally hyperbolic and M admits future time infinity i+. lambdaM coincides with Minkowski vacuum if M is Minkowski spacetime. It is now proved that, in the general case of a curved spacetime M, the state lambdaM enjoys the following further properties. (1) lambdaM is invariant under the group of isometries of the bulk spacetime M. (2) lambdaM fulfills a natural energy-positivity condition with respect to every notion of Killing time (if any) in the bulk spacetime M: If M admits a complete time-like Killing vector, the associated one-parameter group of isometries is represented by a strongly-continuous unitary group in the GNS representation of lambdaM. The unitary group has positive self-adjoint generator without zero modes in the one-particle space. (3) lambdaM is (globally) Hadamard in M and thus lambdaM can be used as starting point for perturbative renormalization procedure of QFT of phi in M.

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