Direct Measurement of Photon Recoil from a Levitated Nanoparticle

The momentum transfer between a photon and an object defines a fundamental limit for the precision with which the object can be measured. If the object oscillates at a frequency Ω_{0}, this measurement backaction adds quanta ℏΩ_{0} to the oscillator's energy at a rate Γ_{recoil}, a process call...

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Bibliographic Details
Published in:Physical review letters 2016-06, Vol.116 (24), p.243601-243601, Article 243601
Main Authors: Jain, Vijay, Gieseler, Jan, Moritz, Clemens, Dellago, Christoph, Quidant, Romain, Novotny, Lukas
Format: Article
Language:English
Subjects:
Coherence
Heating
Holes
Momentum transfer
Nanostructure
Photons
Recoil
Reheating
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Summary:The momentum transfer between a photon and an object defines a fundamental limit for the precision with which the object can be measured. If the object oscillates at a frequency Ω_{0}, this measurement backaction adds quanta ℏΩ_{0} to the oscillator's energy at a rate Γ_{recoil}, a process called photon recoil heating, and sets bounds to coherence times in cavity optomechanical systems. Here, we use an optically levitated nanoparticle in ultrahigh vacuum to directly measure Γ_{recoil}. By means of a phase-sensitive feedback scheme, we cool the harmonic motion of the nanoparticle from ambient to microkelvin temperatures and measure its reheating rate under the influence of the radiation field. The recoil heating rate is measured for different particle sizes and for different excitation powers, without the need for cavity optics or cryogenic environments. The measurements are in quantitative agreement with theoretical predictions and provide valuable guidance for the realization of quantum ground-state cooling protocols and the measurement of ultrasmall forces.
ISSN:0031-9007
1079-7114
DOI:10.1103/PhysRevLett.116.243601