Demonstration of improved sensitivity of echo interferometers to gravitational acceleration

TL;DR

This paper presents two configurations of echo interferometers using laser-cooled rubidium atoms to measure gravitational acceleration with unprecedented precision, demonstrating significant improvements over previous methods.

Contribution

It introduces two novel echo interferometer configurations that enhance sensitivity and reduce vibration and magnetic effects, achieving sub-ppb measurement precision of gravitational acceleration.

Findings

Two-pulse AI achieves 6 ppm precision in 25 ms

Three-pulse AI achieves 0.4 ppm precision in 50 ms

Simulations suggest potential for sub-ppb accuracy with optimized setup

Abstract

We have developed two configurations of an echo interferometer that rely on standing wave excitation of a laser-cooled sample of rubidium atoms that measures acceleration. For a two-pulse configuration, the interferometer signal is modulated at the recoil frequency and exhibits a sinusoidal frequency chirp as a function of pulse spacing. For a three-pulse stimulated echo configuration, the signal is observed without recoil modulation and exhibits a modulation at a single frequency. The three-pulse configuration is less sensitive to effects of vibrations and magnetic field curvature leading to a longer experimental timescale. For both configurations of the atom interferometer (AI), we show that a measurement of acceleration with a statistical precision of 0.5% can be realized by analyzing the shape of the echo envelope that has a temporal duration of a few microseconds. Using the two-pulse AI, we obtain measurements of acceleration that are statistically precise to 6 parts per million (ppm) on a 25 ms timescale. Using the three-pulse AI, we obtain measurements of acceleration that are statistically precise to 0.4 ppm on a timescale of 50 ms. A further statistical enhancement is achieved by analyzing the data across the echo envelope to improve the statistical precision to 75 parts per billion (ppb). We discuss methods for reducing prominent systematic effects due to a magnetized vacuum chamber and improving the signal-to-noise ratio. Simulations of both AI configurations with a timescale of 300 ms reached in a non-magnetic vacuum chamber suggest that an optimized experiment with improved vibration isolation and atoms selected in the mF = 0 state can result in measurements of g statistically precise to 0.3 pbb for the two-pulse AI and 0.6 ppb for the three-pulse AI.