Michael J. Hartmann, Moritz E. Reuter, Martin B. Plenio
Published 2005-11-18, updated 2006-03-24Version 2
We consider quantum many body systems as quantum channels and study the relation between the transfer quality and the size of the spectral gap between the system's ground and excited states. In our setup two ancillas are weakly coupled to the quantum many body system at different sites, and we study the propagation of an excitation and quantum information from one ancilla to the other. We observe two different scenarios: a slow, but perfect transfer if the gap large and a fast, but un-complete transfer otherwise. We provide a numerical and analytical approach as well as a simplified physical model explaining our findings. Our results relate the potential of spin chains acting as quantum channels to the concept of quantum phase transitions and offer a different approach to the characterisation of these.
Comments: title changed, figures added
Journal: New J. Phys. 8, 94 (2006)
Spin, angular momentum and spin-statistics for a relativistic quantum many body system
Exotic dynamics of excitation in open Aubry-André-Harper model: Effect of the localization, the dimensionality of the environment and the initial condition
Optimal dynamics for quantum-state and entanglement transfer through homogeneous quantum wires
