Helical particle manipulation based on power-exponent-phase acoustic vortices generated by a sector transducer array

The characteristics of traditional acoustic vortices (AVs) were verified by the cross-sectional axisymmetric pressure distributions with perfect phase spirals around the center pressure null. In order to generate a non-axisymmetric pressure distribution, the concept of power-exponent-phase was first...

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Published inChinese physics B Vol. 32; no. 6; pp. 64304 - 385
Main Authors Wang, Qingdong, Hu, Yantao, Wang, Shengli, Li, Hongyu
Format Journal Article
LanguageEnglish
Published Chinese Physical Society and IOP Publishing Ltd 01.05.2023
College of Ocean Science and Engineering,Shandong University of Science and Technology,Qingdao 266590,China%Department of Modern Architecture,Linyi Vocational College,Linyi 276017,China
Subjects
acoustic vortices
particle manipulation
power-exponent-phase
sector transducer array
spiral potential well
particle manipulation
power-exponent-phase
acoustic vortices
sector transducer array
spiral potential well
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Abstract The characteristics of traditional acoustic vortices (AVs) were verified by the cross-sectional axisymmetric pressure distributions with perfect phase spirals around the center pressure null. In order to generate a non-axisymmetric pressure distribution, the concept of power-exponent-phase was first introduced into the formation of AV beams, named “power-exponent-phase acoustic vortices (PAVs)” in this paper. Based on a ring-array of sector transducers, the helical distribution of the low-pressure valley in cross-sections of PAVs, which enables particles to move from a distant position to the center low-potential well along a certain spiral passageway, was proved theoretically. The particle manipulation behavior for PAVs with a power order of 2 is numerically modeled and experimentally confirmed. The results show that PAVs with a non-axisymmetric spiral pressure distribution can be used to realize the directional transport of particles in an enlarged scope, suggesting prospective application potential in biomedical engineering.
AbstractList The characteristics of traditional acoustic vortices (AVs) were verified by the cross-sectional axisymmetric pressure distributions with perfect phase spirals around the center pressure null. In order to generate a non-axisymmetric pressure distribution, the concept of power-exponent-phase was first introduced into the formation of AV beams, named “power-exponent-phase acoustic vortices (PAVs)” in this paper. Based on a ring-array of sector transducers, the helical distribution of the low-pressure valley in cross-sections of PAVs, which enables particles to move from a distant position to the center low-potential well along a certain spiral passageway, was proved theoretically. The particle manipulation behavior for PAVs with a power order of 2 is numerically modeled and experimentally confirmed. The results show that PAVs with a non-axisymmetric spiral pressure distribution can be used to realize the directional transport of particles in an enlarged scope, suggesting prospective application potential in biomedical engineering.
Author Li, Hongyu
Wang, Qingdong
Hu, Yantao
Wang, Shengli
AuthorAffiliation College of Ocean Science and Engineering,Shandong University of Science and Technology,Qingdao 266590,China%Department of Modern Architecture,Linyi Vocational College,Linyi 276017,China
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Keywords particle manipulation
power-exponent-phase
acoustic vortices
sector transducer array
spiral potential well
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Snippet The characteristics of traditional acoustic vortices (AVs) were verified by the cross-sectional axisymmetric pressure distributions with perfect phase spirals...
The characteristics of traditional acoustic vortices(AVs)were verified by the cross-sectional axisymmetric pressure distributions with perfect phase spirals...
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SubjectTerms acoustic vortices
particle manipulation
power-exponent-phase
sector transducer array
spiral potential well
Title Helical particle manipulation based on power-exponent-phase acoustic vortices generated by a sector transducer array
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