Approximate universality and large measurement gain of Rabi model in a linear potential under strong Doppler broadening

TL;DR

This paper theoretically investigates the Rabi model in a linear potential under strong Doppler broadening, revealing approximate universality and high measurement gain, which could enhance atom gravimeter sensitivity.

Contribution

It derives a generic scalar Riccati equation for the Rabi model and demonstrates the robustness of phase-rotation measurements under strong Doppler effects using Fisher information.

Findings

High metrological gain under strong Doppler broadening

Approximate universality of phase-rotation protocols

Theoretical foundation for noise-resistant atom gravimeters

Abstract

Harnessing quantum resources in the atomic external degrees of freedom, particularly matter-wave states with large momentum broadening, holds significant potential for enhancing the sensitivity of Kasevich-Chu atom gravimeters at the standard quantum limit. However, a fully quantum-mechanical investigation of the critical Doppler effect inherent to this approach remains lacking. Employing SU(2) Lie group theory, we derive a generic scalar Riccati equation governing the unitary dynamics of the Rabi model within a linear potential and analyze the Doppler effect's impact on Rabi oscillations because of the strong coupling between the internal and external states. Furthermore, by integrating Fisher information theory, we demonstrate the approximate universality and high metrological gain of phase-rotation measurement protocols under strong Doppler broadening induced by large-momentum width. This theoretical work provides insightful implications for broader generalization, such as extensions to finite-temperature scenarios or multi-pulse sequences, exemplified by the $\pi/2-\pi-\pi/2$ pulse sequence characteristic of Kasevich-Chu atom gravimeters. Thus this study lays a theoretical foundation for developing high-sensitivity, noise-resistant atom gravimeters that leverage external-state quantum resources.