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

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 apert...

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Bibliographic Details
Published in:Applied physics letters Vol. 123; no. 8
Main Authors: Plaskocinski, T., Arita, Y., Bruce, G. D., Persheyev, S., Dholakia, K., Di Falco, A., Ohadi, H.
Format: Journal Article
Language:English
Published: Melville American Institute of Physics 21-08-2023
Subjects:
Applied physics
Carbon dioxide
Carbon dioxide lasers
Circular polarization
Diameters
Laser ablation
Nanoparticles
Numerical aperture
Optical components
Optical trapping
Optical traps
Polarized light
Rotation
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Summary: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.
ISSN:0003-6951
1077-3118
DOI:10.1063/5.0155512