Fundamental Uncertainties in Nonequilibrium Atom-Field Interactions
POSTER
Abstract
Atomic clouds represent one of the the main workhorses for modern and future quantum technologies. A precise understanding of their fundamental physical limitations is a crucial task in the strive for miniaturized and fully integrated quantum sensors.
We explore the use of stochastic methods to describe the fundamental uncertainties in nonequilibrium atom-field interactions. Our approach can be of use in the design and interpretation of future generations of quantum sensors.
We explore the use of stochastic methods to describe the fundamental uncertainties in nonequilibrium atom-field interactions. Our approach can be of use in the design and interpretation of future generations of quantum sensors.
Publication: D. Reiche, F. Intravaia, K. Busch, <br>Wading through the void: Exploring quantum friction and nonequilibrium fluctuations, APL Photonics 7, 030902 (2022).<br><br>H. Dong, D. Reiche, J.-T. Hsiang, B.-L. Hu, Quantum Thermodynamic Uncertainties in Nonequilibrium Systems from Robertson-Schrödinger Relations, Entropy 24, 870 (2022).<br><br>D. Reiche, J.-T. Hsiang, B.-L. Hu, Quantum Thermodynamic Uncertainty Relations, Generalized Current Fluctuations and Nonequilibrium Fluctuation–Dissipation Inequalities, Entropy 24, 1016 (2022).
Presenters
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Daniel Reiche
Humboldt University of Berlin
Authors
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Daniel Reiche
Humboldt University of Berlin