Numerical investigation of particle deflection in tilted-angle standing surface acoustic wave microfluidic devices

•Numerical model developed for particle trajectories in acoustofluidic separation.•Effect of related parameters of acoustic and flow fields on trajectories is analyzed.•Two-stage separation demonstrated for exosome-sized particles from whole blood.•The model has potential for optimal design of acous...

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Bibliographic Details
Published in:Applied Mathematical Modelling 2022-01, Vol.101, p.517-532
Main Authors: Peng, Tao, Zhou, Mingyong, Yuan, Shuai, Fan, Cui, Jiang, Bingyan
Format: Article
Language:English
Subjects:
Acoustofluidic device
Biocompatibility
Deflection
Design optimization
Drag
Flow velocity
Lithium niobates
Mathematical models
Microfluidic devices
Microspheres
Numerical models
Numerical simulation
Particle deflection
Polystyrene resins
Robustness (mathematics)
Sound waves
Surface acoustic wave
Surface acoustic waves
Viscous drag
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Summary:•Numerical model developed for particle trajectories in acoustofluidic separation.•Effect of related parameters of acoustic and flow fields on trajectories is analyzed.•Two-stage separation demonstrated for exosome-sized particles from whole blood.•The model has potential for optimal design of acoustofluidic separation systems. The tilted-angle standing surface acoustic wave (taSSAW) microfluidic device has become a powerful tool for biosample separation due to its biocompatibility and non-contact, label-free, and high-efficiency nature. Studying and modeling particle deflection in a microfluid environment containing a taSSAW field is essential in the design of robust taSSAW-based microfluidic devices. Here, we present a numerical model taking into consideration fluid viscous drag force and the acoustic radiation force induced by scattering of acoustic waves for the study of particle deflection. The reliability of the model is validated by comparing our predictions with data from existing literature. In order to support our prediction experimentally, we fabricated a taSSAW microfluidic chip using 128° YX LiNbO3, and the deflection results for 3- and 7-μm polystyrene microspheres concur with the numerical estimation. The effects on particle deflection by parameters such as pre-focusing, pre-focusing width, average flow velocity, acoustic pressure amplitude, tilted angle, and surface acoustic wave frequency on particle deflection are then analyzed. This model could be used to optimize the design and better understand the mechanism of taSSAW microfluidic devices.
ISSN:0307-904X
1088-8691
0307-904X
DOI:10.1016/j.apm.2021.07.018