Stabilizing nanoparticles in the intensity minimum: feedback levitation on an inverted potential
We demonstrate the stable trapping of a levitated nanoparticle on top of an inverted potential using a combination of optical readout and electrostatic control. The feedback levitation on an inverted potential (FLIP) method stabilizes the particle at an intensity minimum. By using a Kalman-filter-ba...
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Zusammenfassung: | We demonstrate the stable trapping of a levitated nanoparticle on top of an
inverted potential using a combination of optical readout and electrostatic
control. The feedback levitation on an inverted potential (FLIP) method
stabilizes the particle at an intensity minimum. By using a Kalman-filter-based
linear-quadratic-Gaussian (LQG) control method, we confine a particle to within
$\sigma_x = (9.0 \pm 0.5) nm$ of the potential maximum at an effective
temperature of $(16 \pm 1) K$ in a room-temperature environment. Despite drifts
in the absolute position of the potential maximum, we can keep the nanoparticle
at the apex by estimating the drift from the particle dynamics using the Kalman
filter. Our approach may enable new levitation-based sensing schemes with
enhanced bandwidth. It also paves the way for optical levitation at zero
intensity of an optical potential, which alleviates decoherence effects due to
material-dependent absorption and is hence relevant for macroscopic quantum
experiments. |
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DOI: | 10.48550/arxiv.2410.17253 |