Gate fidelity, dephasing, and "magic" trapping of optically trapped neutral atom

TL;DR

This paper models the quantum motion of optically trapped neutral atoms to analyze and improve gate fidelity and coherence times, proposing a 'magic' trapping condition for enhanced quantum control.

Contribution

It introduces a quantum oscillator model for atomic motion, revealing new methods to enhance gate fidelity and coherence via cooling and specific vibrational states.

Findings

Gate fidelity limited by atom temperature

Dephasing can rephase if differential frequency is stable

Cooling and 'magic' trapping significantly improve coherence

Abstract

The fidelity of the gate operation and the coherence time of neutral atoms trapped in an optical dipole trap are figures of merit for the applications. The motion of the trapped atom is one of the key factors which influence the gate fidelity and coherence time. The motion has been considered as a classical oscillator in analyzing the influence. Here we treat the motion of the atom as a quantum oscillator. The population on the vibrational states of the atom are considered in analyzing the gate fidelity and decoherence. We show that the fidelity of a coherent rotation gate is dramatically limited by the temperature of a thermally trapped atom. We also show that the dephasing between the two hyperfine states due to the thermal motion of the atom could rephase naturally if the differential frequency shift is stable and the vibrational states do not change. The decoherence due to the fluctuations of the trap laser intensity is also discussed. Both the gate fidelity and coherence time can be dramatically enhanced by cooling the atom into vibrational ground states and/or by using a blue-detuned trap. More importantly, we propose a "magic" trapping condition by preparing the atom into specific vibrational states.