6  GHz hyperfast rotation of an optically levitated nanoparticle in vacuum

Jin, Yuanbin; Yan, Jiangwei; Rahman, Shah; Li, Jie; Yu, Xudong; Zhang, Jing

doi:10.1364/prj.422975

Cited by 44 publications

(32 citation statements)

References 47 publications

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“…which is equivalent to (51) for negligible damping γ m = 0 in the bulk. Like in (50), the superconductor acts like a mirror for the fluctuations generated in the dielectric layer.…”

Section: B Half-space Covered By Thin Surface Layermentioning

confidence: 99%

“…For instance, the rotation states of molecular ions have been proposed for quantum information processing [7,8,10,12,13,39,40], promising significant advantages in comparison to harmonic degrees of freedom due to the special topology of rotations in three dimensions [11]. At the same time, experiments with levitated nanorotors [41][42][43][44][45][46][47][48][49][50][51] reach millikelvin rotational temperatures [48,50,52], pointing the path towards ultra-precise torque sensors [41,43,44,46,47,49,51,53], the search for new physics [54], and tests of the quantum superposition principle with massive objects [52,[55][56][57][58].…”

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confidence: 99%

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Surface-induced decoherence and heating of charged particles

Martinetz,

Hornberger,

Stickler

2022

Preprint

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Levitating charged particles in ultra-high vacuum provides a preeminent platform for quantum information processing, for quantum-enhanced force and torque sensing, for probing physics beyond the standard model, and for high-mass tests of the quantum superposition principle. Existing setups range from single atomic ions, to ion chains and crystals, to charged molecules and nanoparticles. Future technological applications of such quantum systems will be crucially affected by fluctuating electric fields emanating from nearby electrodes, which interact with the levitated particles' monopole and higher charge moments. In this article, we provide a theoretical toolbox for describing how the rotational and translational quantum dynamics of charged nano-to microscale objects is affected by near metallic and dielectric surfaces, as characterized by their macroscopic dielectric response. The resulting quantum master equations describe the coherent surface-particle interaction, due to image charges and Casimir-Polder potentials, as well as surface-induced decoherence and heating, with the experimentally observed frequency and distance scaling. We explicitly evaluate the master equations for typical charge distributions and types of motion, thereby providing the tools required for describing and mitigating surface-induced decoherence in a variety of experiments with charged objects.

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“…which is equivalent to (51) for negligible damping γ m = 0 in the bulk. Like in (50), the superconductor acts like a mirror for the fluctuations generated in the dielectric layer.…”

Section: B Half-space Covered By Thin Surface Layermentioning

confidence: 99%

mentioning

confidence: 99%

Surface-induced decoherence and heating of charged particles

Martinetz,

Hornberger,

Stickler

2022

Preprint

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“…A beam of such polarisation can stably trap and continuously rotate mesoscopic particles: by reducing the ambient pressure in a levitated geometry in vacuum, extraordinarily high spin rates may be available when operating micron-sized birefringent particles in vacuum [4]. By extending to smaller particles, rotation rates of several GHz have recently been demonstrated [5][6][7][8]. These achievements provide unprecedented access to a relatively unexplored physical regime.…”

Section: Introductionmentioning

confidence: 99%

Cooling the optical-spin driven limit cycle oscillations of a levitated gyroscope

Arita¹,

Simpson²,

Bruce³

et al. 2022

Preprint

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The non-conservative, azimuthal forces associated with inhomogeneous optical-spin angular momentum play a critical role in optical trapping. Intriguingly, birefringent microspheres can be stably levitated and rapidly rotated in circularly polarized optical traps in ultra-high vacuum whereas isotropic spheres are typically destabilized and expelled, even at relatively modest pressures. Here we show that the resolution of this apparent key paradox rests in the form of the orientationally averaged, effective forces acting on the spinning birefringent particle. In particular, the effective azimuthal component is heavily suppressed and highly non-linear. As a consequence, non-conservative effects are strongly, if imperfectly, inhibited. Their influence is apparent only at very low pressures where we observe the formation of noisy, nano-scale limit cycles or orbits. Finally, we show how parametric feedback can synthesize a form of dissipation, necessary to preserve limit cycle oscillation, without introducing additional thermal fluctuations. This allows the preparation of highly coherent, self-sustained oscillations with effective temperatures on the order of a milliKelvin. The tailoring of azimuthal spin forces through the material structure of a spinning, non-spherical particle opens up new opportunities for the design of ultra stable optical rotors. In addition, we have shown that the unique profile of the azimuthal force, featured in this work, allows for the formation of nano-scale limit cycles that can be stabilized and cooled. In principle, this approach could enable the cooling of limit cycles into the quantum regime, allowing for experimental realisation of quantum synchronization, or alternative ways of entangling mesoscopic bodies.

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“…Recently, the temperature of the CoM motion of a nanoparticle has been cooled to the quantum ground state 18 , which can be used to research macroscopic quantum phenomenon such as the Schrodinger's cat state [19][20][21] . Moreover, the optically levitated nanoparticle systems have been studied for measuring the Casimir force and torque 22,23 , and GHz scale rotation was recently observed 22,[24][25][26] , including the record-breaking ultrahigh rotation frequency of about 6 GHz by our group 26 .…”

mentioning

confidence: 99%

Imaging the dipole scattering of an optically levitated dielectric nanoparticle

Jin,

Yan,

Rahman

et al. 2021

Preprint

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6 GHz hyperfast rotation of an optically levitated nanoparticle in vacuum

Cited by 44 publications

References 47 publications

Surface-induced decoherence and heating of charged particles

Surface-induced decoherence and heating of charged particles

Cooling the optical-spin driven limit cycle oscillations of a levitated gyroscope

Imaging the dipole scattering of an optically levitated dielectric nanoparticle

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