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On the acoustically induced fluid flow in particle separation systems employing standing surface acoustic waves – Part I

Sebastian Sachs, Mostafa Baloochi, Christian Cierpka, Jörg König

2022Lab on a Chip45 citationsDOIOpen Access PDF

Abstract

to periodic flows resembling the pseudo-standing wave field is revealed. An adaptation of the electrical power, however, only affects the velocity scaling. Based on the experimental data, a validated numerical model was developed in which critical material parameters and boundary conditions were systematically adjusted. Considering a Navier slip length at the substrate-fluid interface, the simulations provide a strong agreement with the measured velocity data over a large frequency range and enable an energetic consideration of the first and second-order fields. Based on the results of this study, critical parameters were identified for the particle size as well as for channel height and width. Progress for the research on SAW-based separation systems is obtained not only by these findings but also by providing all experimental velocity data to allow for further developments on other sites.

Topics & Concepts

Standing waveAcousticsParticle (ecology)Acoustic waveSeparation (statistics)Flow (mathematics)MechanicsMaterials scienceSurface (topology)Particle flowSurface acoustic wavePhysicsComputer scienceGeologyMathematicsOceanographyGeometryMachine learningDiscrete element methodMicrofluidic and Bio-sensing TechnologiesMicrofluidic and Capillary Electrophoresis ApplicationsElectrostatics and Colloid Interactions
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