Generation of spherical vortex beams to trap large particles for enhanced axial force

Recent studies have shown the possibility to manipulate small elastic spheres in 3D with a single-sided beam. Acoustical tweezers are very appealing because they provide a fine spatial control of the motion of a single particle in space. Their main limitations are due to the weak restoring axial for...

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Bibliographic Details
Published in:Ultrasonics 2021-03, Vol.111, p.106296-106296, Article 106296
Main Authors: Zhao, D., Thomas, J.-L., Marchiano, R.
Format: Article
Language:English
Subjects:
Acoustical tweezers
Acoustics
Mechanics
Physics
Radiation pressure
Resonating spherical target
Single beam tweezers
Spherical vortex beam
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Summary:Recent studies have shown the possibility to manipulate small elastic spheres in 3D with a single-sided beam. Acoustical tweezers are very appealing because they provide a fine spatial control of the motion of a single particle in space. Their main limitations are due to the weak restoring axial force and improving this force is still a challenge. We show theoretically that the spherical vortex beams can trap large particles and enhance the axial force. Indeed, the special features of these unusual beams look like the bottle beams in optics. Nevertheless, their spatial complexity presupposes that they can be produced with sufficient precision. Therefore, attention is paid to the synthesis of the spherical vortices. A method based on the inverse filter method is proposed. It allows to synthesize them with a very good precision since the theoretical force is recovered experimentally with an error smaller than 10%. Then, the spherical vortices are used to trap polyethylene beads with radii between 500 and 590µm. Experiments show that the radial trap is working while no beads have been trapped in the axial direction. This failure is analyzed in detail and is shown to be mainly due to sensitivity to the properties of the materials which influences the resonance modes of the elastic sphere. This study paves the way to the optimization of acoustical tweezers for the manipulation of large objects. •Acoustic manipulation with radiation pressure can be obtained with acoustical tweezers.•Acoustical tweezers with single sided beam provide selectivity.•Spherical vortices enhance the axial radiation force.•Large particles enhance selectivity and force amplitude.•The role of resonances and anti-resonances of sphere scattering is emphasized.
ISSN:0041-624X
1874-9968
DOI:10.1016/j.ultras.2020.106296