Three alternative model-building strategies using quasi-Hermitian time-dependent observables

Abstract

A (K+1)-plet of non-Hermitian and time-dependent operators (say, j(t), j=0,1,…,K) can be interpreted as the set of observables characterizing a unitary quantum system. What is required is the existence of a self-adjoint and, in general, time-dependent operator (say, (t) called inner product metric) making the operators quasi-Hermitian, j(t)(t)=(t)j(t). The theory (called non-Hermitian interaction-picture, NIP) requires a separate description of the evolution of the states (t) (realized, via Schr\"odinger-type equation, by a generator, say, G(t)) and of the observables themselves (a different generator (say, (t)(t)) occurs in the related non-Hermitian Heisenberg-type equation). Every j(t) (and, in particular, Hamiltonian H(t)=0(t)) appears isospectral to its hypothetical isospectral and self-adjoint (but, by assumption, prohibitively user-unfriendly) avatar λj(t)=(t)j(t)-1(t) with (t)(t)=(t). In our paper the key role played by identity H(t)=G(t)+(t) is shown to imply that there exist just three alternative meaningful implementations of the NIP approach, viz., ``number one'' (a ``dynamical'' strategy based on the knowledge of H(t)), ``number two'' (a ``kinematical'' one, based on the Coriolis force (t)) and ``number three'' (in the literature, such a construction based on G(t) is most popular but, paradoxically, it is also most complicated).