Robert Weser scite author profile

Acoustic streaming has emerged as a promising technique for refined microscale manipulation, where strong rotational flow can give rise to particle and cell capture. In contrast to hydrodynamically generated vortices, acoustic streaming is rapidly tunable, highly scalable and requires no external pressure source. Though streaming is typically ignored or minimized in most acoustofluidic systems that utilize other acoustofluidic effects, we maximize the effect of acoustic streaming in a continuous flow using a high-frequency (381 MHz), narrow-beam focused surface acoustic wave. This results in rapid fluid streaming, with velocities orders of magnitude greater than that of the lateral flow, to generate fluid vortices that extend the entire width of a 400 μm wide microfluidic channel. We characterize the forces relevant for vortex formation in a combined streaming/lateral flow system, and use these acoustic streaming vortices to selectively capture 2 μm from a mixed suspension with 1 μm particles and human breast adenocarcinoma cells (MDA-231) from red blood cells.

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3D measurement and simulation of surface acoustic wave driven fluid motion: a comparison

Kiebert

Wege

Massing

et al. 2017

Lab Chip

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The characterisation of the fluid motion induced by the acoustic streaming effect is of paramount interest for novel microfluidic devices based on surface acoustic waves (SAWs), e.g. for a detailed description of the achievable mixing efficiency and thus the design of such devices. Here, we present for the first time a quantitative 3D comparison between experimental measurements and numerical simulations of the acoustic streaming induced fluid flow inside a microchannel originating from a SAW. On the one hand, we performed fully three-dimensional velocity measurements using the astigmatism particle tracking velocimetry. On the other hand, we derived a novel streaming force approach solving the damped wave equation, which allows fast and easy 3D simulations of the acoustic streaming induced fluid flow. Furthermore, measurements of the SAW amplitude profile inside the fluid filled microchannel were performed. Based on these results, we obtained a very good agreement between the velocity measurements and the simulations of the fluid flow demonstrating the importance of comprising the actual shape of the SAW amplitude profile for quantitatively reliable simulations. It is shown that the novel streaming force approach is a valid approximation for the simulation of the acoustic streaming induced fluid flow, allowing a rapid and simple estimation of the flow field of SAW based microfluidic devices.

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Converse Magnetoelectric Composite Resonator for Sensing Small Magnetic Fields

Hayes

Jovičević‐Klug

Toxvaerd

et al. 2019

Sci Rep

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Magnetoelectric (ME) thin film composites consisting of sputtered piezoelectric (PE) and magnetostrictive (MS) layers enable for measurements of magnetic fields passively, i.e. an AC magnetic field directly generates an ME voltage by mechanical coupling of the MS deformation to the PE phase. In order to achieve high field sensitivities a magnetic bias field is necessary to operate at the maximum piezomagnetic coefficient of the MS phase, harnessing mechanical resonances further enhances this direct ME effect size. Despite being able to detect very small AC field amplitudes, exploiting mechanical resonances directly, implies a limitation to available signal bandwidth along with the inherent inability to detect DC or very low frequency magnetic fields. The presented work demonstrates converse ME modulation of thin film Si cantilever composites of mesoscopic dimensions (25 mm × 2.45 mm × 0.35 mm), employing piezoelectric AlN and magnetostrictive FeCoSiB films of 2 µm thickness each. A high frequency mechanical resonance at about 515 kHz leads to strong induced voltages in a surrounding pickup coil with matched self-resonance, leading to field sensitivities up to 64 kV/T. A DC limit of detection of 210 pT/Hz1/2 as well as about 70 pT/Hz1/2 at 10 Hz, without the need for a magnetic bias field, pave the way towards biomagnetic applications.

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Particle characterisation in highly concentrated dispersions using ultrasonic backscattering method

et al. 2013

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The complexity of surface acoustic wave fields used for microfluidic applications

Weser

Winkler

Weihnacht³

et al. 2020

Ultrasonics

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Towards efficient surface acoustic wave (SAW)-based microfluidic actuators

Winkler

Brunig

Faust

et al. 2016

Sensors and Actuators A: Physical

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Three-dimensional heating and patterning dynamics of particles in microscale acoustic tweezers

et al. 2022

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Particle characterization in highly concentrated suspensions by ultrasound scattering method

Weser¹,

Wöckel²,

Hempel³

et al. 2013

Sensors and Actuators A: Physical

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Robert Weser

Selective particle and cell capture in a continuous flow using micro-vortex acoustic streaming

3D measurement and simulation of surface acoustic wave driven fluid motion: a comparison

Converse Magnetoelectric Composite Resonator for Sensing Small Magnetic Fields

Particle characterisation in highly concentrated dispersions using ultrasonic backscattering method

The complexity of surface acoustic wave fields used for microfluidic applications

Towards efficient surface acoustic wave (SAW)-based microfluidic actuators

Three-dimensional heating and patterning dynamics of particles in microscale acoustic tweezers

Particle characterization in highly concentrated suspensions by ultrasound scattering method

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