Acoustic manipulating of capsule-shaped particle assisted by phononic crystal plate

In this work, we present theoretical analyses of the acoustic radiation force acting on non-spherical particles, as well as experimental demonstration of particle trapping assisted by the artificially engineered acoustic field of the phononic crystal plate. The capsule-shaped particles, a kind of co...

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Veröffentlicht in:	Applied physics letters 2018-05, Vol.112 (22)
Hauptverfasser:	Li, Hengyi, Wang, Yang, Ke, Manzhu, Peng, Shasha, Liu, Fengming, Qiu, Chunyin, Liu, Zhengyou
Format:	Artikel
Sprache:	eng
Schlagworte:	Acoustics Applied physics Crystals Dependence Drug delivery systems Sound waves Trapping
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container_title	Applied physics letters
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creator	Li, Hengyi Wang, Yang Ke, Manzhu Peng, Shasha Liu, Fengming Qiu, Chunyin Liu, Zhengyou
description	In this work, we present theoretical analyses of the acoustic radiation force acting on non-spherical particles, as well as experimental demonstration of particle trapping assisted by the artificially engineered acoustic field of the phononic crystal plate. The capsule-shaped particles, a kind of common non-spherical-shaped particles, in practical cases, are chosen as study objects. The dependence of the acoustic radiation force on different parameters such as the frequency, position, and orientation of a capsule-shaped particle is evaluated, and the analysis shows the orientation angle also has a great influence, which is quite different from the spherical particles. Due to the extraordinary resonant transmission of the phononic crystal plate, the periodically distributed acoustic field is obtained to realize trapping on capsule-shaped particle(s). This method could be envisaged to pave a way of delivering drugs or cells and small fibers in biology and medicine.
doi_str_mv	10.1063/1.5022704
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subjects	Acoustics Applied physics Crystals Dependence Drug delivery systems Sound waves Trapping
title	Acoustic manipulating of capsule-shaped particle assisted by phononic crystal plate
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