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Autori principali: Spielman, Sarah E., Thomas, Sage M., Teofilovska, Maja, van Blerkom, Annick C, Bauroth-Sherman, Juniper J., Chlanda, Nicolaus A., Conley, Hannah S., Conte, Philip A., Kirk, Aidan D., Carroll, Thomas J., Noel, Michael W.
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2512.22110
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author Spielman, Sarah E.
Thomas, Sage M.
Teofilovska, Maja
van Blerkom, Annick C
Bauroth-Sherman, Juniper J.
Chlanda, Nicolaus A.
Conley, Hannah S.
Conte, Philip A.
Kirk, Aidan D.
Carroll, Thomas J.
Noel, Michael W.
author_facet Spielman, Sarah E.
Thomas, Sage M.
Teofilovska, Maja
van Blerkom, Annick C
Bauroth-Sherman, Juniper J.
Chlanda, Nicolaus A.
Conley, Hannah S.
Conte, Philip A.
Kirk, Aidan D.
Carroll, Thomas J.
Noel, Michael W.
contents One explanation of the thermalization of an isolated quantum system is the eigenstate thermalization hypothesis, which posits that all energy eigenstates are thermal. Based on this idea, we use dynamical typicality to predict the thermal state of ultracold Rb atoms exchanging energy via long-range dipole-dipole interactions. In a magneto-optical trap, we excite the atoms to the center of a manifold of nearly harmonically spaced clusters of Stark energy levels and then allow them to equilibrate. Comparing the equilibrium state to our thermal prediction across a range of densities, we find that the atoms generally fail to thermalize, though they approach the thermal state at the highest tested density.
format Preprint
id arxiv_https___arxiv_org_abs_2512_22110
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Thermalization within a Stark manifold through Rydberg atom interactions
Spielman, Sarah E.
Thomas, Sage M.
Teofilovska, Maja
van Blerkom, Annick C
Bauroth-Sherman, Juniper J.
Chlanda, Nicolaus A.
Conley, Hannah S.
Conte, Philip A.
Kirk, Aidan D.
Carroll, Thomas J.
Noel, Michael W.
Quantum Physics
One explanation of the thermalization of an isolated quantum system is the eigenstate thermalization hypothesis, which posits that all energy eigenstates are thermal. Based on this idea, we use dynamical typicality to predict the thermal state of ultracold Rb atoms exchanging energy via long-range dipole-dipole interactions. In a magneto-optical trap, we excite the atoms to the center of a manifold of nearly harmonically spaced clusters of Stark energy levels and then allow them to equilibrate. Comparing the equilibrium state to our thermal prediction across a range of densities, we find that the atoms generally fail to thermalize, though they approach the thermal state at the highest tested density.
title Thermalization within a Stark manifold through Rydberg atom interactions
topic Quantum Physics
url https://arxiv.org/abs/2512.22110