Clocked atom delivery to a photonic crystal waveguide

Clocked atom delivery to a photonic crystal waveguide

Experiments and numerical simulations are described that develop quantitative understanding of atomic motion near the surfaces of nanoscopic photonic crystal waveguides (PCWs). Ultracold atoms are delivered from a moving optical lattice into the PCW. Synchronous with the moving lattice, transmission...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 116; no. 2; pp. 456 - 465
Main Authors: Burgers, A. P., Peng, L. S., Muniz, J. A., McClung, A. C., Martin, M. J., Kimble, H. J.
Format: Journal Article
Language:English
Published: United States National Academy of Sciences 08-01-2019
National Academy of Sciences, Washington, DC (United States)
Series:PNAS Plus
Subjects:
atoms
Atoms & subatomic particles
Calibration
CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS
Computer simulation
Crystal lattices
Mapping
MATERIALS SCIENCE
nanophotonics
Optical lattices
Optics
Photonic crystals
Photonics
Physical Sciences
PNAS Plus
quantum optics
surface forces
Time dependence
Trajectory control
Vacuum
Waveguides
nanophotonics
surface forces
quantum optics
atoms
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Summary:Experiments and numerical simulations are described that develop quantitative understanding of atomic motion near the surfaces of nanoscopic photonic crystal waveguides (PCWs). Ultracold atoms are delivered from a moving optical lattice into the PCW. Synchronous with the moving lattice, transmission spectra for a guided-mode probe field are recorded as functions of lattice transport time and frequency detuning of the probe beam. By way of measurements such as these, we have been able to validate quantitatively our numerical simulations, which are based upon detailed understanding of atomic trajectories that pass around and through nanoscopic regions of the PCW under the influence of optical and surface forces. The resolution for mapping atomic motion is roughly 50 nm in space and 100 ns in time. By introducing auxiliary guided-mode (GM) fields that provide spatially varying AC Stark shifts, we have, to some degree, begun to control atomic trajectories, such as to enhance the flux into the central vacuum gap of the PCW at predetermined times and with known AC Stark shifts. Applications of these capabilities include enabling high fractional filling of optical trap sites within PCWs, calibration of optical fields within PCWs, and utilization of the time-dependent, optically dense atomic medium for novel nonlinear optical experiments.
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National Science Foundation (NSF)
89233218CNA000001; N00014-16-1-2399; N00014-15-1-2761; FA9550-16-1-0323; PHY-1205729; PHY-1125565
US Department of the Navy, Office of Naval Research (ONR)
US Air Force Office of Scientific Research (AFOSR)
LA-UR-18-29096
3Present address: Department of Electrical and Computer Engineering, University of Massachusetts Amherst, Amherst, MA 01003.
Contributed by H. J. Kimble, November 7, 2018 (sent for review October 8, 2018; reviewed by Julien Laurat and Vladan Vuletic)
Author contributions: A.P.B., L.S.P., J.A.M., M.J.M., and H.J.K. designed research; A.P.B., L.S.P., J.A.M., A.C.M., and M.J.M. performed research; A.P.B., L.S.P., and A.C.M. contributed new reagents/analytic tools; A.P.B. and L.S.P. analyzed data; and A.P.B., L.S.P., and H.J.K. wrote the paper.
2Present address: JILA, University of Colorado, Boulder, CO 80309.
4Present address: Physics Division, Los Alamos National Laboratory, Los Alamos, NM 87545.
Reviewers: J.L., Laboratoire Kastler Brossel, Sorbonne Université; and V.V., Massachusetts Institute of Technology.
1A.P.B. and L.S.P. contributed equally to this work.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1817249115