Towards hybrid quantum systems: Trapping a single atom near a nanoscale solid-state structure

Towards hybrid quantum systems: Trapping a single atom near a nanoscale solid-state structure

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We describe and demonstrate a method to deterministically trap single atoms near nanoscale solid-state objects. The trap is formed by the interference of an optical tweezer and its reflection from the nano object, creating a one-dimensional optical lattice where the first lattice site is at z0 ∼ λ/4...

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Main Authors: Tiecke T.G., Thompson J.D., Feist J., Akimov A., Zibrov A., Vuletić V., Lukin M.D.
Format: Article
Language:English
Published: EDP Sciences 2013-08-01
Series:EPJ Web of Conferences
Online Access:http://dx.doi.org/10.1051/epjconf/20135703002
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spelling doaj-184df3e3b2dc43f292abfde19be4d88f2021-08-02T01:22:25ZengEDP SciencesEPJ Web of Conferences2100-014X2013-08-01570300210.1051/epjconf/20135703002Towards hybrid quantum systems: Trapping a single atom near a nanoscale solid-state structureTiecke T.G.Thompson J.D.Feist J.Akimov A.Zibrov A.Vuletić V.Lukin M.D.We describe and demonstrate a method to deterministically trap single atoms near nanoscale solid-state objects. The trap is formed by the interference of an optical tweezer and its reflection from the nano object, creating a one-dimensional optical lattice where the first lattice site is at z0 ∼ λ/4 from the surface. Using a tapered optical fiber as the nanoscopic object, we characterize the loading into different lattice sites by means of the AC-Stark shift induced by a guided fiber mode. We demonstrate a loading efficiency of 94(6)% into the first lattice site, and measure the cooperativity for the emission of the atom into the guided mode of the nanofiber. We show that by tailoring the dimensions of the nanofiber the distance of the trap to the surface can be adjusted. This method is applicable to a large variety of nanostructures and represents a promising starting point for interfacing single atoms with arbitrary nanoscale solid-state systems. http://dx.doi.org/10.1051/epjconf/20135703002
collection DOAJ
language English
format Article
sources DOAJ
author Tiecke T.G.
Thompson J.D.
Feist J.
Akimov A.
Zibrov A.
Vuletić V.
Lukin M.D.
spellingShingle Tiecke T.G.
Thompson J.D.
Feist J.
Akimov A.
Zibrov A.
Vuletić V.
Lukin M.D.
Towards hybrid quantum systems: Trapping a single atom near a nanoscale solid-state structure
EPJ Web of Conferences
author_facet Tiecke T.G.
Thompson J.D.
Feist J.
Akimov A.
Zibrov A.
Vuletić V.
Lukin M.D.
author_sort Tiecke T.G.
title Towards hybrid quantum systems: Trapping a single atom near a nanoscale solid-state structure
title_short Towards hybrid quantum systems: Trapping a single atom near a nanoscale solid-state structure
title_full Towards hybrid quantum systems: Trapping a single atom near a nanoscale solid-state structure
title_fullStr Towards hybrid quantum systems: Trapping a single atom near a nanoscale solid-state structure
title_full_unstemmed Towards hybrid quantum systems: Trapping a single atom near a nanoscale solid-state structure
title_sort towards hybrid quantum systems: trapping a single atom near a nanoscale solid-state structure
publisher EDP Sciences
series EPJ Web of Conferences
issn 2100-014X
publishDate 2013-08-01
description We describe and demonstrate a method to deterministically trap single atoms near nanoscale solid-state objects. The trap is formed by the interference of an optical tweezer and its reflection from the nano object, creating a one-dimensional optical lattice where the first lattice site is at z0 ∼ λ/4 from the surface. Using a tapered optical fiber as the nanoscopic object, we characterize the loading into different lattice sites by means of the AC-Stark shift induced by a guided fiber mode. We demonstrate a loading efficiency of 94(6)% into the first lattice site, and measure the cooperativity for the emission of the atom into the guided mode of the nanofiber. We show that by tailoring the dimensions of the nanofiber the distance of the trap to the surface can be adjusted. This method is applicable to a large variety of nanostructures and represents a promising starting point for interfacing single atoms with arbitrary nanoscale solid-state systems.
url http://dx.doi.org/10.1051/epjconf/20135703002
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