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Trapped Ion Quantum Computing
Feedback Cooling of an Insulating High-Q Diamagnetically Levitated Plate
arXiv
Authors: S. Tian, K. Jadeja, D. Kim, A. Hodges, G. C. Hermosa, C. Cusicanqui, R. Lecamwasam, J. E. Downes, J. Twamley
Year
2023
Paper ID
52900
Status
Preprint
Abstract Read
~2 min
Abstract Words
183
Citations
N/A
Abstract
Levitated systems in vacuum have many potential applications ranging from new types of inertial and magnetic sensors through to fundamental issues in quantum science, the generation of massive Schrodinger cats, and the connections between gravity and quantum physics. In this work, we demonstrate the passive, diamagnetic levitation of a centimeter-sized massive oscillator which is fabricated using a novel method that ensures that the material, though highly diamagnetic, is an electrical insulator. By chemically coating a powder of microscopic graphite beads with silica and embedding the coated powder in high-vacuum compatible wax, we form a centimeter-sized thin square plate which magnetically levitates over a checkerboard magnet array. The insulating coating reduces eddy damping by almost an order of magnitude compared to uncoated graphite with the same particle size. These plates exhibit a different equilibrium orientation to pyrolytic graphite due to their isotropic magnetic susceptibility. We measure the motional quality factor to be Q 1.58*10^5 for an approximately centimeter-sized composite resonator with a mean particle size of 12 microns. Further, we apply delayed feedback to cool the vertical motion of frequency 19 Hz from room temperature to 320 millikelvin.
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- This paper contributes to the Trapped-Ion Quantum Computing research area in the Quantum Articles archive.
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- Levitated systems in vacuum have many potential applications ranging from new types of inertial and magnetic sensors through to fundamental issues in quantum science, the...
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