Mesoscopic quantum switching of a Bose-Einstein condensate in an optical lattice governed by the parity of the number of atoms

Abstract

It is shown that for a N-boson system the parity of N can be responsible for a qualitative difference in the system response to variation of a parameter. The nonlinear boson model is considered, which describes tunneling of boson pairs between two distinct modes X1,2 of the same energy and applies to a Bose-Einstein condensate in an optical lattice. By varying the lattice depth one induces the parity-dependent quantum switching, i.e. X1 X2 for even N and X1 X1 for odd N, for arbitrarily large N. A simple scheme is proposed for observation of the parity effect on the mesoscopic scale by using the bounce switching regime, which is insensitive to the initial state preparation (as long as only one of the two Xl modes is significantly populated), stable under small perturbations and requires an experimentally accessible coherence time.