Fast and accurate circularization of a Rydberg atom

TL;DR

This paper introduces a quantum optimal control approach to rapidly and accurately prepare circular Rydberg states, surpassing existing methods in speed and fidelity within experimental constraints.

Contribution

It develops optimized radio-frequency pulses for fast, high-fidelity circularization of Rydberg atoms using quantum control theory, considering practical experimental limitations.

Findings

Achieves high-fidelity circularization in minimal time

Proposes pulse shapes within current experimental constraints

Discusses fundamental quantum speed limits for the process

Abstract

Preparation of a so-called circular state in a Rydberg atom where the projection of the electron angular momentum takes its maximum value is challenging due to the required amount of angular momentum transfer. Currently available protocols for circular state preparation are either accurate but slow or fast but error-prone. Here, we show how to use quantum optimal control theory to derive pulse shapes that realize fast and accurate circularization of a Rydberg atom. In particular, we present a theoretical proposal for optimized radio-frequency pulses that achieve high fidelity in the shortest possible time, given current experimental limitations on peak amplitudes and spectral bandwidth. We also discuss the fundamental quantum speed limit for circularization of a Rydberg atom, when lifting these constraints.