In a double-well potential, a Bose-Einstein condensate exhibits Josephson
oscillations or self-trapping, depending on its initial preparation and on the
ratio of inter-particle interaction to inter-well tunneling. Here, we elucidate
the role of the exchange symmetry for the dynamics with a mixture of two
distinguishable species with identical physical properties, i.e. which are
governed by an isospecific interaction and external potential. In the
mean-field limit, the spatial population imbalance of the mixture can be
described by the dynamics of a single species in an effective potential with
modified properties or, equivalently, with an effective total particle number.
The oscillation behavior can be tuned by populating the second species while
maintaining the spatial population imbalance and all other parameters constant.
In the corresponding many-body approach, the single-species description
approximates the full counting statistics well also outside the realm of
spin-coherent states. The method is extended to general Bose-Hubbard systems
and to their classical mean-field limits, which suggests an effective
single-species description of multicomponent Bose gases with weakly
an-isospecific interactions.Comment: amended and expanded, accepted for Phys. Rev. A, 14 pages, 7 figure