Bogoliubov theory of interacting bosons: new insights from an old problem

Abstract

In a gas of N interacting bosons, the Hamiltonian Hc, obtained by dropping all the interaction terms between free bosons with moment k0, is diagonalized exactly. The resulting eigenstates |\:S,\:k,\:η\: depend on two discrete indices S,\:η=0,\:1,\:…, where η numerates the quasiphonons carrying a moment k, responsible for transport or dissipation processes. S, in turn, numerates a ladder of vacua\:|\:S,\:k,\:0\:, with increasing equispaced energies, formed by boson pairs with opposite moment. Passing from one vacuum to another (S→ S1), results from creation/annihilation of new momentless collective excitations, that we call vacuons. Exact quasiphonons originate from one of the vacua by creating\:an asymmetry in the number of opposite moment bosons. The well known Bogoliubov collective excitations (CEs) are shown to coincide with the exact eigenstates |\:0,\:k,\:η\:, i.e. with the quasiphonons created from the lowest-level vacuum (S=0). All this is discussed, in view of existing or future experimental observations of the vacuons (PBs), a sort of bosonic Cooper pairs, which are the main factor of novelty beyond Bogoliubov theory.