Three-dimensional cooling and detection of a nanosphere with a single cavity

Zhang Qi Yin; Tongcang Li; M. Feng

doi:10.1103/PhysRevA.83.013816

Three-dimensional cooling and detection of a nanosphere with a single cavity

Zhang Qi Yin^*
, Tongcang Li
, M. Feng

^*Corresponding author for this work

CAS - Innovation Academy for Precision Measurement Science and Technology
University of Science and Technology of China
University of Texas at Austin

Research output: Contribution to journal › Article › peer-review

51 Citations (Scopus)

Abstract

We propose an experimental scheme to cool and measure the three-dimensional (3D) motion of an optically trapped nanosphere in a cavity. Driven by three lasers on TEM00, TEM01, and TEM10 modes, a single cavity can cool a trapped nanosphere to the quantum ground states in all three dimensions under the resolved-sideband condition. Our scheme can also detect an individual collision between a single molecule and a cooled nanosphere efficiently. Such an ability can be used to measure the mass of molecules and the surface temperature of the nanosphere. We also discuss the heating induced by the intensity fluctuation, the pointing instability, and the phase noise of lasers, and justify the feasibility of our scheme under current experimental conditions.

Original language	English
Article number	013816
Journal	Physical Review A - Atomic, Molecular, and Optical Physics
Volume	83
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevA.83.013816
Publication status	Published - 19 Jan 2011
Externally published	Yes

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abstract = "We propose an experimental scheme to cool and measure the three-dimensional (3D) motion of an optically trapped nanosphere in a cavity. Driven by three lasers on TEM00, TEM01, and TEM10 modes, a single cavity can cool a trapped nanosphere to the quantum ground states in all three dimensions under the resolved-sideband condition. Our scheme can also detect an individual collision between a single molecule and a cooled nanosphere efficiently. Such an ability can be used to measure the mass of molecules and the surface temperature of the nanosphere. We also discuss the heating induced by the intensity fluctuation, the pointing instability, and the phase noise of lasers, and justify the feasibility of our scheme under current experimental conditions.",

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AU - Yin, Zhang Qi

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N2 - We propose an experimental scheme to cool and measure the three-dimensional (3D) motion of an optically trapped nanosphere in a cavity. Driven by three lasers on TEM00, TEM01, and TEM10 modes, a single cavity can cool a trapped nanosphere to the quantum ground states in all three dimensions under the resolved-sideband condition. Our scheme can also detect an individual collision between a single molecule and a cooled nanosphere efficiently. Such an ability can be used to measure the mass of molecules and the surface temperature of the nanosphere. We also discuss the heating induced by the intensity fluctuation, the pointing instability, and the phase noise of lasers, and justify the feasibility of our scheme under current experimental conditions.

AB - We propose an experimental scheme to cool and measure the three-dimensional (3D) motion of an optically trapped nanosphere in a cavity. Driven by three lasers on TEM00, TEM01, and TEM10 modes, a single cavity can cool a trapped nanosphere to the quantum ground states in all three dimensions under the resolved-sideband condition. Our scheme can also detect an individual collision between a single molecule and a cooled nanosphere efficiently. Such an ability can be used to measure the mass of molecules and the surface temperature of the nanosphere. We also discuss the heating induced by the intensity fluctuation, the pointing instability, and the phase noise of lasers, and justify the feasibility of our scheme under current experimental conditions.

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Three-dimensional cooling and detection of a nanosphere with a single cavity

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