Absolute quantum gravimeters and gradiometers for field measurements

TL;DR

This paper discusses the development and performance of absolute quantum gravimeters and gradiometers, highlighting their high sensitivity, robustness, and ability to provide continuous, long-term gravity measurements in various environments.

Contribution

It presents the reproducible high performance of 16 quantum gravimeter units and recent advances in differential quantum gravimeters measuring gravity and its gradient.

Findings

Achieved l level performance on all 16 units

Measured gravity gradient at 10 nm/s^2 level

Demonstrated continuous long-term gravity data collection

Abstract

Gravity measurements provide valuable information on the mass distribution below the earth surface relevant to various areas of geosciences such as hydrology, geodesy, geophysics, volcanology, and natural resources management. During the past decades, the needs for sensitivity, robustness, compactness, and transportability of instruments measuring the gravitational acceleration have constantly increased. Today, applications typically call for 1 $\mu \mathrm{Gal} = 10 \mathrm{nm.s}^{-2}$ ~ $10^{-9}$ g resolution on time scales ranging from minutes to years. Absolute Quantum Gravimeters (AQGs) based on matter-wave interferometry with laser-cooled atoms address all these challenges at once, even in uncontrolled environments. Furthermore, to date, quantum gravimeters are the only technology capable of providing continuous absolute gravity data over long measurement durations (~1 day to months or more). In this paper we recall the AQG working principle and present the reproducible high performance at the {\mu}Gal level on all 16 units fabricated so far. We also describe recent progress on the Differential Quantum Gravimeter (DQG) which measures simultaneously the mean gravitational acceleration and its vertical gradient at the level of $10 \mathrm{nm.s}^{-2}$ and $1$ E (1 E[eotvos] = $10^{-9}$ s$^{-2}$) respectively.