Continuous dynamical decoupling of spin chains: Inducing two-qubit interactions to generate perfect entanglement

TL;DR

This paper introduces a method using combined static and oscillating fields to control and generate near-perfect entanglement between any two spins in a chain, even with noise, by decoupling from the environment and tuning interactions.

Contribution

It presents a novel control technique that simultaneously decouples spin chains from noise and enables precise manipulation of spin-spin interactions for entanglement generation.

Findings

Achieves near-perfect entanglement between any two spins.

Effective noise decoupling in various spin chain models.

Tunable interactions to produce Bell states.

Abstract

Efficient control over entanglement in spin chains is useful for quantum information processing applications. In this paper, we propose the use of a combination of two different configurations of strong static and oscillating fields to control and generate near-perfect entanglement between any two spins in a spin chain, even in the presence of noise. This is made possible by the fact that our control fields not only decouple the spin chain from its environment but also selectively modify the spin-spin interactions. By suitably tuning these spin-spin interactions via the control fields, we show that the quantum state of any two spins in the spin chain can be made to be a Bell state. We illustrate our results for various spin chains, such as the XY model, the XYZ model, and the Ising spin chain.