Anisotropy and asymptotic degeneracy of the physical-Hilbert-space inner-product metrics in an exactly solvable crypto-unitary quantum model

Abstract

In quantum mechanics (formulated, say, in Schr\"odinger picture) only the knowledge of a complete set of observables j enables us to declare the related physical inner product (i.e., the Hilbert-space metric such that j =\,j, i.e., such that =(j)) unique. In many applications people simplify the model and consider just a single input observable (mostly an energy-representing Hamiltonian 1=H) and pick up, out of all of the eligible metrics =(H), just the simplest candidate (typically, in the case of the special self-adjoint input H we virtually always work with trivial =I). As long as this forces us to admit only the self-adjoint forms of any other input observable j, the scope of the theory is, without any truly meaningful phenomenological reason, restricted. In our present paper we describe a strictly non-numerical N by N matrix model in which such a restriction is replaced by another, phenomenologically non-equivalent restriction in which ≠ I and in which the system reaches a collapse (i.e., a loss-of-bservability catastrophe) via unitary evolution.