We study the quality of state and entanglement transmission through quantum channels described by spin chains varying both the system parameters and the initial state of the channel. We consider a vast class of one-dimensional many-body models which contains some of the most relevant experimental realizations of quantum data buses. In particular, we consider spin-$1/2$ $\mathit{XY}$ and $\mathit{XXZ}$ models with open boundary conditions. Our results show a significant difference between free-fermionic (noninteracting) systems ($\mathit{XY}$) and interacting ones ($\mathit{XXZ}$), where in the former case initialization can be exploited for improving the entanglement distribution, while in the latter case it also determines the quality of state transmission. In fact, we find that in noninteracting systems the exchange with fermions in the initial state of the chain always has a destructive effect, and we prove that it can be completely removed in the isotropic $\mathit{XX}$ model by initializing the chain in a ferromagnetic state. On the other hand, in interacting systems constructive effects can arise by scattering between hopping fermions and a proper initialization procedure. Our results are an example in which state and entanglement transmission show maxima at different points as the interactions and initializations of spin chain channels are varied.

• Received 2 April 2011

DOI:https://doi.org/10.1103/PhysRevA.83.062328