Prospects of Trapping Atoms with an Optical Dipole Trap in a Deep Parabolic Mirror for Light–Matter‐Interaction Experiments

Sondermann, Markus; Fischer, Martin S.; Leuchs, Gerd

doi:10.1002/qute.202000022

Adv Quantum Tech

2020

DOI: 10.1002/qute.202000022

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Prospects of Trapping Atoms with an Optical Dipole Trap in a Deep Parabolic Mirror for Light–Matter‐Interaction Experiments

Markus Sondermann

Martin S. Fischer

Gerd Leuchs

Abstract: The prospects of employing a deep parabolic mirror as a focusing device for trapping neutral atoms in an optical dipole trap are evaluated. It is predicted that such a dipole trap will result in a deep trapping potential as well as in a small spatial spread of the atom's center of mass wave function already for a Doppler cooled atom. This strong confinement is beneficial for many applications, one of which is the increase of the interaction strength between an atom and a light field focused from full solid ang… Show more

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References 42 publications

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Laser writing of parabolic micromirrors with a high numerical aperture for optical trapping and rotation

Plaskocinski,

Arita,

Bruce

et al. 2023

Applied Physics Letters

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On-chip optical trapping systems allow for high scalability and lower the barrier to access. Systems capable of trapping multiple particles typically come with high cost and complexity. Here, we present a technique for making parabolic mirrors with micrometer-size dimensions and high numerical apertures (NA > 1). Over 350 mirrors are made by simple CO2 laser ablation of glass followed by gold deposition. We fabricate mirrors of arbitrary diameter and depth at a high throughput rate by carefully controlling the ablation parameters. We use the micromirrors for three-dimensional optical trapping of microbeads in solution, achieving a maximum optical trap stiffness of 52 pN/μm/W. We, then, further demonstrate the viability of the mirrors as in situ optical elements through the rotation of a vaterite particle using reflected circularly polarized light. The method used allows for rapid and highly customizable fabrication of dense optical arrays.

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Laser writing of parabolic micromirrors with a high numerical aperture for optical trapping and rotation

Plaskocinski,

Arita,

Bruce

et al. 2023

Applied Physics Letters

View full text Add to dashboard Cite

show abstract

Quantum jump photodetector for narrowband photon counting with a single atom

Zarraoa,

Veyron,

Lamich

et al. 2024

Phys. Rev. Research

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Using a single neutral Rb87 atom held in an optical trap, and “quantum jump” detection of single-photon-initiated state changes, we demonstrate a single-photon quantum jump photodetector (QJPD) with intrinsically narrow bandwidth and strong rejection of out-of-band photons, of interest for detecting weak optical signals in the presence of a strong broadband background. By analyzing fluorescence photon count distributions for the bright and dark states with and without excitation, we measure quantum efficiency of 2.9(2)×10−3, a record for single-pass quantum jump production, and signal-photon-unprovoked “dark jump” rate—analogous to the dark count rate of other detectors —of 3(10)×10−3jumps/s during passive accumulation plus 4.0(4)×10−3 jumps per readout, orders of magnitude below those of traditional single-photon detectors. Available methods can substantially improve QJPD quantum efficiency, dark jump rate, bandwidth, and tunability. Published by the American Physical Society 2024

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Prospects of Trapping Atoms with an Optical Dipole Trap in a Deep Parabolic Mirror for Light–Matter‐Interaction Experiments

Cited by 2 publications

References 42 publications

Laser writing of parabolic micromirrors with a high numerical aperture for optical trapping and rotation

Laser writing of parabolic micromirrors with a high numerical aperture for optical trapping and rotation

Quantum jump photodetector for narrowband photon counting with a single atom

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