Elliptical orbits of microspheres in an evanescent field

Lulu Liu; Simon Kheifets; Vincent Ginis; Andrea Di Donato; Federico Capasso

doi:10.1073/pnas.1714953114

Elliptical orbits of microspheres in an evanescent field

Lulu Liu, Simon Kheifets, Vincent Ginis, Andrea Di Donato, Federico Capasso

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

15 Citations (Scopus)

Abstract

We examine the motion of periodically driven and optically tweezed microspheres in fluid and find a rich variety of dynamic regimes. We demonstrate, in experiment and in theory, that mean particle motion in 2D is rarely parallel to the direction of the applied force and can even exhibit elliptical orbits with nonzero orbital angular momentum. The behavior is unique in that it depends neither on the nature of the microparticles nor that of the excitation; rather, angular momentum is introduced by the particle’s interaction with the anisotropic fluid and optical trap environment. Overall, we find this motion to be highly tunable and predictable.

Original language	English
Pages (from-to)	11087-11091
Number of pages	5
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	114
Issue number	42
DOIs	https://doi.org/10.1073/pnas.1714953114
Publication status	Published - 17 Oct 2017

Keywords

Colloids
Elliptical motion
Evanescent field
Microparticles
Optical forces

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title = "Elliptical orbits of microspheres in an evanescent field",

abstract = "We examine the motion of periodically driven and optically tweezed microspheres in fluid and find a rich variety of dynamic regimes. We demonstrate, in experiment and in theory, that mean particle motion in 2D is rarely parallel to the direction of the applied force and can even exhibit elliptical orbits with nonzero orbital angular momentum. The behavior is unique in that it depends neither on the nature of the microparticles nor that of the excitation; rather, angular momentum is introduced by the particle{\textquoteright}s interaction with the anisotropic fluid and optical trap environment. Overall, we find this motion to be highly tunable and predictable.",

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AU - Liu, Lulu

AU - Kheifets, Simon

AU - Ginis, Vincent

AU - Di Donato, Andrea

AU - Capasso, Federico

PY - 2017/10/17

Y1 - 2017/10/17

N2 - We examine the motion of periodically driven and optically tweezed microspheres in fluid and find a rich variety of dynamic regimes. We demonstrate, in experiment and in theory, that mean particle motion in 2D is rarely parallel to the direction of the applied force and can even exhibit elliptical orbits with nonzero orbital angular momentum. The behavior is unique in that it depends neither on the nature of the microparticles nor that of the excitation; rather, angular momentum is introduced by the particle’s interaction with the anisotropic fluid and optical trap environment. Overall, we find this motion to be highly tunable and predictable.

AB - We examine the motion of periodically driven and optically tweezed microspheres in fluid and find a rich variety of dynamic regimes. We demonstrate, in experiment and in theory, that mean particle motion in 2D is rarely parallel to the direction of the applied force and can even exhibit elliptical orbits with nonzero orbital angular momentum. The behavior is unique in that it depends neither on the nature of the microparticles nor that of the excitation; rather, angular momentum is introduced by the particle’s interaction with the anisotropic fluid and optical trap environment. Overall, we find this motion to be highly tunable and predictable.

KW - Colloids

KW - Elliptical motion

KW - Evanescent field

KW - Microparticles

KW - Optical forces

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JF - Proceedings of the National Academy of Sciences of the United States of America

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ER -

Elliptical orbits of microspheres in an evanescent field

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