Ballistic quantum state transfer in spin chains: general theory for quasi-free models and arbitrary initial states

TL;DR

This paper reviews and generalizes ballistic quantum-state transfer protocols in spin chains, demonstrating high-quality transmission at finite temperatures through control of boundary qubits in quasi-free models.

Contribution

It provides new analytical results for XX, XY, and Ising models and shows how boundary control can mitigate thermal effects for robust state transfer.

Findings

Analytical results for XX, XY, and Ising models.

Boundary control cancels thermal effects.

High-quality transmission at finite temperature.

Abstract

Ballistic quantum-information transfer through spin chains is based on the idea of making the spin dynamics ruled by collective excitations with linear dispersion relation. Unlike perfect state transfer schemes, a ballistic transmission requires only a minimal engineering of the interactions; in fact, for most practical purposes, the optimization of the couplings to the ends of the chain is sufficient to obtain an almost perfect transmission. In this work we review different ballistic quantum-state transfer protocols based on the dynamics of quasi-free spin chains, and further generalize them both at zero and finite temperature. In particular, besides presenting novel analytical results for XX, XY, and Ising spin models, it is shown how, via a complete control on the first and last two qubits of the chain, destructive thermal effects can be cancelled, leading to a high-quality state transmission irrespective of the temperature.