Robust acoustic particle manipulation: A thin-reflector design for moving particles to a surface | Zendy

Peter GlynneJones | Zendy; Rosemary J. Boltryk | Zendy; Martyn Hill | Zendy; Nick Harris | Zendy; P. Baclet | Zendy

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Robust acoustic particle manipulation: A thin-reflector design for moving particles to a surface

Author(s) -

Peter GlynneJones,

Rosemary J. Boltryk,

Martyn Hill,

Nick Harris,

P. Baclet

Publication year - 2009

Publication title -

the journal of the acoustical society of america

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 0.619

H-Index - 187

eISSN - 1520-8524

pISSN - 0001-4966

DOI - 10.1121/1.3186800

Subject(s) - reflector (photography) , distributed bragg reflector , materials science , acoustics , optics , lossy compression , surface (topology) , layer (electronics) , surface wave , optoelectronics , computer science , physics , nanotechnology , wavelength , geometry , light source , mathematics , artificial intelligence

Existing ultrasonic manipulation devices capable of pushing particles to a surface ("quarter-wave" devices) have significant potential in sensor applications. A configuration for achieving this that uses the first thickness resonance of a layered structure with both a thin reflector layer and thin-fluid layer is described here. Crucially, this mode is efficient with lossy reflector materials such as polymers, produces a more uniform acoustic radiation force at the reflector, and is less sensitive to geometric variations than previously described quarter-wave devices. This design is thus expected to be suitable for mass produced, disposable devices.

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