Litcius/Paper detail

Acoustophoresis in polymer-based microfluidic devices: Modeling and experimental validation

Fabian Lickert, Mathias Ohlin, Henrik Bruus, Pelle Ohlsson

2021The Journal of the Acoustical Society of America36 citationsDOIOpen Access PDF

Abstract

A finite-element model is presented for numerical simulation in three dimensions of acoustophoresis of suspended microparticles in a microchannel embedded in a polymer chip and driven by an attached piezoelectric transducer at MHz frequencies. In accordance with the recently introduced principle of whole-system ultrasound resonances, an optimal resonance mode is identified that is related to an acoustic resonance of the combined transducer-chip-channel system and not to the conventional pressure half-wave resonance of the microchannel. The acoustophoretic action in the microchannel is of comparable quality and strength to conventional silicon-glass or pure glass devices. The numerical predictions are validated by acoustic focusing experiments on 5-μm-diameter polystyrene particles suspended inside a microchannel, which was milled into a polymethylmethacrylate chip. The system was driven anti-symmetrically by a piezoelectric transducer, driven by a 30-V peak-to-peak alternating voltage in the range from 0.5 to 2.5 MHz, leading to acoustic energy densities of 13 J/m3 and particle focusing times of 6.6 s.

Topics & Concepts

MicrochannelMicrofluidicsAcousticsAcoustic resonancePiezoelectricityMaterials scienceTransducerResonance (particle physics)Ultrasonic sensorParticle (ecology)Sound pressureMicroelectromechanical systemsPolystyrenePressure sensorRange (aeronautics)Energy (signal processing)UltrasoundFlow (mathematics)MicropumpVoltageParticle velocityPiezoelectric sensorQuality (philosophy)MicroactuatorSIGNAL (programming language)Microfluidic and Bio-sensing TechnologiesUltrasound and Cavitation PhenomenaUltrasound Imaging and Elastography