$Quantum time reflection and refraction of ultracold atoms$

Quantum time reflection and refraction of ultracold atoms

Time reflection and refraction are temporal analogies of the spatial boundary effects derived from Fermat's principle. They occur when classical waves strike a time boundary where an abrupt change in the properties of the medium is introduced. The main features of time-reflected and refracted w...

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Veröffentlicht in:	arXiv.org 2023-03
Hauptverfasser:	Dong, Zhaoli, Li, Hang, Wan, Tuo, Liang, Qian, Yang, Zhaoju, Yan, Bo
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Sprache:	eng
Schlagworte:	Fermat principle Lattices Many body problem Momentum Optical materials Optics Physics - Atomic Physics Physics - Mesoscale and Nanoscale Physics Physics - Optics Physics - Quantum Gases Reflection Refracted waves Refraction Steering Ultracold atoms
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description	Time reflection and refraction are temporal analogies of the spatial boundary effects derived from Fermat's principle. They occur when classical waves strike a time boundary where an abrupt change in the properties of the medium is introduced. The main features of time-reflected and refracted waves are the shift of frequency and conservation of momentum, which offer a new degree of freedom for steering extreme waves and controlling phases of matter. The concept was originally proposed for manipulating optical waves more than five decades ago. However, due to the extreme challenges in the ultrafast engineering of the optical materials, the experimental realization of the time boundary effects remains elusive. Here, we introduce a time boundary into a momentum lattice of ultracold atoms and simultaneously demonstrate the time reflection and refraction experimentally. Through launching a Gaussian-superposed state into the Su-Schrieffer-Heeger (SSH) atomic chain, we observe the time-reflected and refracted waves when the input state strikes a time boundary. Furthermore, we detect a transition from time reflection/refraction to localization with increasing strength of disorder and show that the time boundary effects are robust against considerable disorder. Our work opens a new avenue for future exploration of time boundaries and spatiotemporal lattices, and their interplay with non-Hermiticity and many-body interactions.
doi_str_mv	10.48550/arxiv.2303.02963
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subjects	Fermat principle Lattices Many body problem Momentum Optical materials Optics Physics - Atomic Physics Physics - Mesoscale and Nanoscale Physics Physics - Optics Physics - Quantum Gases Reflection Refracted waves Refraction Steering Ultracold atoms
title	Quantum time reflection and refraction of ultracold atoms
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