Capillary-based, multifunctional manipulation of particles and fluids via focused surface acoustic waves

Surface acoustic wave (SAW)-enabled acoustofluidic technologies have recently atttracted increasing attention for applications in biology, chemistry, biophysics, and medicine. Most SAW acoustofluidic devices generate acoustic energy which is then transmitted into custom microfabricated polymer-based...

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Veröffentlicht in:	Journal of physics. D, Applied physics Applied physics, 2024-08, Vol.57 (30), p.305401
Hauptverfasser:	Pei, Zhichao, Tian, Zhenhua, Yang, Shujie, Shen, Liang, Hao, Nanjing, Naquin, Ty D, Li, Teng, Sun, Lining, Rong, Weibin, Huang, Tony Jun
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Sprache:	eng
Schlagworte:	acoustofluidics droplet generation in-capillary particle manipulation particle manipulation surface acoustic waves
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container_title	Journal of physics. D, Applied physics
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creator	Pei, Zhichao Tian, Zhenhua Yang, Shujie Shen, Liang Hao, Nanjing Naquin, Ty D Li, Teng Sun, Lining Rong, Weibin Huang, Tony Jun
description	Surface acoustic wave (SAW)-enabled acoustofluidic technologies have recently atttracted increasing attention for applications in biology, chemistry, biophysics, and medicine. Most SAW acoustofluidic devices generate acoustic energy which is then transmitted into custom microfabricated polymer-based channels. There are limited studies on delivering this acoustic energy into convenient commercially-available glass tubes for manipulating particles and fluids. Herein, we have constructed a capillary-based SAW acoustofluidic device for multifunctional fluidic and particle manipulation. This device integrates a converging interdigitated transducer to generate focused SAWs on a piezoelectric chip, as well as a glass capillary that transports particles and fluids. To understand the actuation mechanisms underlying this device, we performed finite element simulations by considering piezoelectric, solid mechanic, and pressure acoustic physics. This experimental study shows that the capillary-based SAW acoustofluidic device can perform multiple functions including enriching particles, patterning particles, transporting particles and fluids, as well as generating droplets with controlled sizes. Given the usefulness of these functions, we expect that this acoustofluidic device can be useful in applications such as pharmaceutical manufacturing, biofabrication, and bioanalysis.
doi_str_mv	10.1088/1361-6463/ad415a
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subjects	acoustofluidics droplet generation in-capillary particle manipulation particle manipulation surface acoustic waves
title	Capillary-based, multifunctional manipulation of particles and fluids via focused surface acoustic waves
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