What question did this study set out to answer?

The aim is to develop a compact quantum gravimeter with long-term stability and high sensitivity.

February 14, 2026

A field-deployable compact gravimeter based on a grating magneto-optical trap with μGal-level long-term stability

Key Points

The aim is to develop a compact quantum gravimeter with long-term stability and high sensitivity.
Developed a gravimeter utilizing a grating magneto-optical trap with 87Rb atoms.
Integrated components include magnetic shielding, optical parts, and a classical seismometer.
Evaluated stability and sensitivity under field conditions.
Achieved a sensitivity of 270 μGal/Hz.
Demonstrated long-term stability of 5 μGal over a one-hour average.
Gravity measurements correlated well with a theoretical tidal model.

Abstract

We present a compact quantum gravimeter based on a grating magneto-optical trap using 87Rb atoms that achieves μGal-level long-term stability without passive vibration isolation. The sensor head integrates magnetic shielding, an ion pump, optical components, and a classical seismometer within a total volume of less than 75L. The gravimeter achieves a sensitivity of 270 μGal/Hz and a stability of 5 μGal at a 1-h average with the long-term gravity record in good agreement with the theoretical tidal model. These results demonstrate a field-deployable platform for portable and chip-integrable quantum gravimetry.

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A field-deployable compact gravimeter based on a grating magneto-optical trap with μGal-level long-term stability

Key Points

Abstract

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