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Main Authors: Panda, Cristian D., Tao, Matthew J., Ceja, Miguel, Müller, Holger
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2310.01344
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author Panda, Cristian D.
Tao, Matthew J.
Ceja, Miguel
Müller, Holger
author_facet Panda, Cristian D.
Tao, Matthew J.
Ceja, Miguel
Müller, Holger
contents Despite being the dominant force of nature on large scales, gravity remains relatively elusive to experimental measurement. Many questions remain, such as its behavior at small scales or its role in phenomena ascribed to dark matter and dark energy. Atom interferometers are powerful tools for probing Earth's gravity, the gravitational constant, dark energy theories and general relativity. However, they typically use atoms in free fall, which limits the measurement time to only a few seconds, and to even briefer intervals when measuring the interaction of the atoms with a stationary source mass. Recently, interferometers with atoms suspended for as long as 70 seconds in an optical lattice have been demonstrated. To keep the atoms from falling, however, the optical lattice must apply forces that are billion-fold as strong as the putative signals, so even tiny imperfections reduce sensitivity and generate complex systematic effects. As a result, lattice interferometers have yet to demonstrate precision and accuracy on par with their free fall counterparts and have yet to be used for precision measurement. Here, we optimize the sensitivity of a lattice interferometer and use a system of signal inversions and switches to suppress and quantify systematic effects. This enables us to measure the attraction of a miniature source mass, ruling out the existence of screened dark energy theories over their natural parameter space. More importantly, the combined accuracy of $6.2~\rm{nm/s}^2$ is four times as good as the best similar measurements with freely falling atoms, demonstrating the advantages of lattice interferometry in fundamental physics measurements. Further upgrades may enable measuring forces at sub-millimeter ranges, the gravitational Aharonov-Bohm effect and the gravitational constant, compact gravimetry, and testing whether the gravitational field itself has quantum properties.
format Preprint
id arxiv_https___arxiv_org_abs_2310_01344
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Measuring gravity by holding atoms
Panda, Cristian D.
Tao, Matthew J.
Ceja, Miguel
Müller, Holger
Atomic Physics
General Relativity and Quantum Cosmology
High Energy Physics - Experiment
Quantum Physics
Despite being the dominant force of nature on large scales, gravity remains relatively elusive to experimental measurement. Many questions remain, such as its behavior at small scales or its role in phenomena ascribed to dark matter and dark energy. Atom interferometers are powerful tools for probing Earth's gravity, the gravitational constant, dark energy theories and general relativity. However, they typically use atoms in free fall, which limits the measurement time to only a few seconds, and to even briefer intervals when measuring the interaction of the atoms with a stationary source mass. Recently, interferometers with atoms suspended for as long as 70 seconds in an optical lattice have been demonstrated. To keep the atoms from falling, however, the optical lattice must apply forces that are billion-fold as strong as the putative signals, so even tiny imperfections reduce sensitivity and generate complex systematic effects. As a result, lattice interferometers have yet to demonstrate precision and accuracy on par with their free fall counterparts and have yet to be used for precision measurement. Here, we optimize the sensitivity of a lattice interferometer and use a system of signal inversions and switches to suppress and quantify systematic effects. This enables us to measure the attraction of a miniature source mass, ruling out the existence of screened dark energy theories over their natural parameter space. More importantly, the combined accuracy of $6.2~\rm{nm/s}^2$ is four times as good as the best similar measurements with freely falling atoms, demonstrating the advantages of lattice interferometry in fundamental physics measurements. Further upgrades may enable measuring forces at sub-millimeter ranges, the gravitational Aharonov-Bohm effect and the gravitational constant, compact gravimetry, and testing whether the gravitational field itself has quantum properties.
title Measuring gravity by holding atoms
topic Atomic Physics
General Relativity and Quantum Cosmology
High Energy Physics - Experiment
Quantum Physics
url https://arxiv.org/abs/2310.01344