Mass and shape determination of optically levitated nanoparticles

Bart Schellenberg; Mina Morshed Behbahani; Nithesh Balasubramanian; Ties H. Fikkers; Steven Hoekstra

doi:10.1063/5.0166136

Mass and shape determination of optically levitated nanoparticles

Bart Schellenberg, Mina Morshed Behbahani, Nithesh Balasubramanian, Ties H. Fikkers, Steven Hoekstra^*

^*Corresponding author for this work

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Abstract

When introducing a nanoparticle into an optical trap, its mass and shape are not immediately apparent. We combine a charge-based mass measurement with a shape determination method based on light scattering and an analysis of the damping rate anisotropy, all on the same set of silica nanoparticles, trapped using optical tweezers in vacuum. These methods have previously only been used separately, and the mass determination method has not been applied to asymmetric particles before. We demonstrate that the combination of these classification techniques is required to distinguish particles with similar mass but different shape, and vice versa. The ability to identify these parameters is a key step for a range of experiments on precision measurements and sensing using optically levitated nanoparticles.

Original language	English
Article number	114102
Number of pages	7
Journal	Applied Physics Letters
Volume	123
Issue number	11
DOIs	https://doi.org/10.1063/5.0166136
Publication status	Published - 11-Sept-2023

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Mass and shape determination of optically levitated nanoparticlesFinal publisher's version, 1.74 MBLicence: CC BY

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abstract = "When introducing a nanoparticle into an optical trap, its mass and shape are not immediately apparent. We combine a charge-based mass measurement with a shape determination method based on light scattering and an analysis of the damping rate anisotropy, all on the same set of silica nanoparticles, trapped using optical tweezers in vacuum. These methods have previously only been used separately, and the mass determination method has not been applied to asymmetric particles before. We demonstrate that the combination of these classification techniques is required to distinguish particles with similar mass but different shape, and vice versa. The ability to identify these parameters is a key step for a range of experiments on precision measurements and sensing using optically levitated nanoparticles.",

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AU - Schellenberg, Bart

AU - Behbahani, Mina Morshed

AU - Balasubramanian, Nithesh

AU - Fikkers, Ties H.

AU - Hoekstra, Steven

PY - 2023/9/11

Y1 - 2023/9/11

N2 - When introducing a nanoparticle into an optical trap, its mass and shape are not immediately apparent. We combine a charge-based mass measurement with a shape determination method based on light scattering and an analysis of the damping rate anisotropy, all on the same set of silica nanoparticles, trapped using optical tweezers in vacuum. These methods have previously only been used separately, and the mass determination method has not been applied to asymmetric particles before. We demonstrate that the combination of these classification techniques is required to distinguish particles with similar mass but different shape, and vice versa. The ability to identify these parameters is a key step for a range of experiments on precision measurements and sensing using optically levitated nanoparticles.

AB - When introducing a nanoparticle into an optical trap, its mass and shape are not immediately apparent. We combine a charge-based mass measurement with a shape determination method based on light scattering and an analysis of the damping rate anisotropy, all on the same set of silica nanoparticles, trapped using optical tweezers in vacuum. These methods have previously only been used separately, and the mass determination method has not been applied to asymmetric particles before. We demonstrate that the combination of these classification techniques is required to distinguish particles with similar mass but different shape, and vice versa. The ability to identify these parameters is a key step for a range of experiments on precision measurements and sensing using optically levitated nanoparticles.

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JO - Applied Physics Letters

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Mass and shape determination of optically levitated nanoparticles

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