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Bibliographic Details
Main Authors: Màrquez-Mijares, M., Lepetit, B., Brion, E.
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2303.05579
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author Màrquez-Mijares, M.
Lepetit, B.
Brion, E.
author_facet Màrquez-Mijares, M.
Lepetit, B.
Brion, E.
contents We describe a theoretical proposal of a nanofibre-based trap for a Rb$_2$ molecule prepared in the metastable state $(1)^3Σ^+_u$. The trapping potential results from the combination of a travelling and a standing-wave fields, both carried by the fundamental guided mode HE$_{11}$ of the fibre. We show that, with an experimentally realistic choice of laser frequencies and powers, one can implement a $\approx 200$ $μ$K-deep well at $\approx 140$ nm from the fibre surface accomodating for $\approx 500$ translational molecular states.
format Preprint
id arxiv_https___arxiv_org_abs_2303_05579
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Nanofibre-based trap for Rb$_2$ molecule
Màrquez-Mijares, M.
Lepetit, B.
Brion, E.
Quantum Physics
We describe a theoretical proposal of a nanofibre-based trap for a Rb$_2$ molecule prepared in the metastable state $(1)^3Σ^+_u$. The trapping potential results from the combination of a travelling and a standing-wave fields, both carried by the fundamental guided mode HE$_{11}$ of the fibre. We show that, with an experimentally realistic choice of laser frequencies and powers, one can implement a $\approx 200$ $μ$K-deep well at $\approx 140$ nm from the fibre surface accomodating for $\approx 500$ translational molecular states.
title Nanofibre-based trap for Rb$_2$ molecule
topic Quantum Physics
url https://arxiv.org/abs/2303.05579