Optimized pulses for the perturbative decoupling of spin and decoherence bath

TL;DR

This paper develops optimized pulse sequences in nuclear magnetic resonance to decouple a spin from its environment up to third order, enhancing control in quantum systems and quantum information processing.

Contribution

It explicitly designs pulses that cancel first to third order correction terms for spin-bath decoupling, even with a quantum mechanical bath.

Findings

Pulses can be designed to eliminate correction terms up to third order.

Explicit construction of pulses for nd  rotations that counteract bath effects.

Applicable to quantum information processing with quantum baths.

Abstract

In the framework of nuclear magnetic resonance, we consider the general problem of the coherent control of a spin coupled to a bath by means of composite or continuous pulses of duration $\tau_\mathrm{p}$. We show explicity that it is possible to design the pulse in order to achieve a decoupling of the spin from the bath up to the third order in $\tau_\mathrm{p}$. The evolution of the system is separated in the evolution of the spin under the action of the pulse and of the bath times correction terms. We derive the correction terms for a general time dependent axis of rotation and for a general coupling between the spin and the environment. The resulting corrections can be made vanish by an appropriate design of the pulse. For $\pi$ and $\pi/2$ pulses, we demonstrate explicitly that pulses exist which annihilate the first and the second order corrections even if the bath is fully quantum mechanical, i.e., it displays internal dynamics. Such pulses will also be useful for quantum information processing.