Quantization of Big Bang in crypto-Hermitian Heisenberg picture

Abstract

A background-independent quantization of the Universe near its Big Bang singularity is considered using a drastically simplified toy model. Several conceptual issues are addressed. (1) The observable spatial-geometry characteristics of our empty-space expanding Universe is sampled by the time-dependent operator Q=Q(t) of the distance between two space-attached observers (``Alice and Bob''). (2) For any pre-selected guess of the simple, non-covariant time-dependent observable Q(t) one of the Kato's exceptional points (viz., t=τ(EP)) is postulated real-valued. This enables us to treat it as the time of Big Bang. (3) During our ``Eon'' (i.e., at all t>τ(EP)) the observability status of operator Q(t) is mathematically guaranteed by its self-adjoint nature with respect to an ad hoc Hilbert-space metric (t) ≠ I. (4) In adiabatic approximation (i.e., in Heisenberg picture) the passage of the Universe through its t=τ(EP) singularity is interpreted as a quantum phase transition between the preceding and the present Eon. It is worth adding that in our model the widely accepted ``Big Bounce'' regularization of the classical Big Bang singularity after quantization gets replaced by the full-fledged quantum degeneracy. At the quantum-phase-transition singularity, operator Q(τ(EP)) becomes unobservable and acquires a non-diagonalizable Jordan-block structure.