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Light propagation and atom interferometry in gravity and dilaton fields

Fabio Di Pumpo, Alexander Friedrich, Andreas Geyer, Christian Ufrecht, Enno Giese

2024TUbilio (Technical University of Darmstadt)17 citationsDOIOpen Access PDF

Abstract

Dark matter or violations of the Einstein equivalence principle influence the motion of atoms, their internal states as well as electromagnetic fields, thus causing a signature in the signal of atomic detectors. To model such new physics, we introduce dilaton fields and study the modified propagation of light used to manipulate atoms in light-pulse atom interferometers. Their interference signal is dominated by the matter’s coupling to gravity and the dilaton. Even though the electromagnetic field contributes to the phase, no additional dilaton-dependent effect can be observed. However, the light’s propagation in gravity enters via a modified momentum transfer and its finite speed. For illustration, we discuss effects from light propagation and the dilaton on different atom-interferometric setups, including gradiometers, equivalence principle tests, and dark matter detection.

Topics & Concepts

PhysicsDilatonAtom interferometerElectromagnetic fieldEquivalence principle (geometric)Dark matterInterferometryGravitational fieldClassical mechanicsQuantum electrodynamicsAstronomical interferometerQuantum mechanicsAstrophysicsCold Atom Physics and Bose-Einstein CondensatesAdvanced Frequency and Time StandardsAtomic and Subatomic Physics Research
Light propagation and atom interferometry in gravity and dilaton fields | Litcius