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Originalsprache | Englisch |
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Publikationsstatus | Elektronisch veröffentlicht (E-Pub) - 8 Sept. 2020 |
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2020.
Publikation: Arbeitspapier/Preprint › Preprint
}
TY - UNPB
T1 - Precision inertial sensing with quantum gases
AU - Hensel, Thomas
AU - Loriani, Sina
AU - Schubert, Christian
AU - Fitzek, Florian
AU - Abend, Sven
AU - Ahlers, Holger
AU - Siemß, Jan-Nichlas
AU - Hammerer, Klemens
AU - Rasel, Ernst Maria
AU - Gaaloul, Naceur
PY - 2020/9/8
Y1 - 2020/9/8
N2 - Quantum sensors based on light-pulse atom interferometers allow for high-precision measurements of inertial and electromagnetic forces such as the accurate determination of fundamental constants as the fine structure constant or testing foundational laws of modern physics as the equivalence principle. These schemes unfold their full performance when large interrogation times and/or large momentum transfer can be implemented. In this article, we demonstrate how precision interferometry can benefit from the use of Bose-Einstein condensed sources when the state of the art is challenged. We contrast systematic and statistical effects induced by Bose-Einstein condensed sources with thermal sources in three exemplary science cases of Earth- and space-based sensors.
AB - Quantum sensors based on light-pulse atom interferometers allow for high-precision measurements of inertial and electromagnetic forces such as the accurate determination of fundamental constants as the fine structure constant or testing foundational laws of modern physics as the equivalence principle. These schemes unfold their full performance when large interrogation times and/or large momentum transfer can be implemented. In this article, we demonstrate how precision interferometry can benefit from the use of Bose-Einstein condensed sources when the state of the art is challenged. We contrast systematic and statistical effects induced by Bose-Einstein condensed sources with thermal sources in three exemplary science cases of Earth- and space-based sensors.
KW - physics.atom-ph
M3 - Preprint
BT - Precision inertial sensing with quantum gases
ER -