Ring-shaped photoacoustic tweezers for single particle manipulation

Zijie Zhao; Jianping Xia; Tony Jun Huang; Jun Zou

doi:10.1364/OL.447861

Optics Letters
Vol. 47,
Issue 4,
pp. 826-829
(2022)
•https://doi.org/10.1364/OL.447861

Ring-shaped photoacoustic tweezers for single particle manipulation

Zijie Zhao, Jianping Xia, Tony Jun Huang, and Jun Zou

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Zijie Zhao, Jianping Xia, Tony Jun Huang, and Jun Zou, "Ring-shaped photoacoustic tweezers for single particle manipulation," Opt. Lett. 47, 826-829 (2022)

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Table of Contents Category
- Medical Optics and Biotechnology
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About this Article
History
- Original Manuscript: November 8, 2021
- Revised Manuscript: January 4, 2022
- Manuscript Accepted: January 5, 2022
- Published: February 4, 2022

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Abstract

This Letter reports ring-shaped photoacoustic (PA) tweezers that are capable of manipulating single or multiple micron-sized particles. By illuminating a thin layer of an optically absorptive liquid medium with a focused annular pulsed laser beam and a higher pulse repetition rate (e.g., 800 Hz), both acoustic radiation force and instantaneous vaporization repulsion are generated within a certain distance of the illumination region. This makes it possible to conduct continuous and versatile locomotion of single or multiple microparticles. In this Letter, interactions between two or more particles are demonstrated, such as separation, attachment, and grouping of microparticles. The PA tweezers combine some of the advantages of conventional optical and acoustic tweezers and are expected to be a useful alternative approach for the manipulation of microscale objects.

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Supplementary Material (7)

Name	Description
Visualization 1	Recorded video corresponding to Fig.7(a)-(c) showing the manipulation of 8µm particle with instantaneous vaporization repulsion
Visualization 2	Recorded video corresponding to Fig.7(d)-(f) showing the manipulation of 15µm particle with instantaneous vaporization repulsion
Visualization 3	Recorded video corresponding to Fig.8(a)-(c) showing the manipulation of 8µm particle with acoustic radiation force
Visualization 4	Recorded video corresponding to Fig.8(d)-(f) showing the manipulation of 15µm particle with acoustic radiation force
Visualization 5	Recorded video corresponding to Fig.9(a)-(c) showing the attachment of two 15µm particles
Visualization 6	Recorded video corresponding to Fig.9(d)-(f) showing the separation of two 15µm particles
Visualization 7	Recorded video corresponding to Fig.10 showing the grouping of six 8µm particles

Data availability

Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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