Different origins of acoustic streaming at resonance

Jacob Bach, H. Bruus
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引用次数: 3

Abstract

Acoustic streaming is a nonlinear phenomenon that plays an essential role in microscale acoustofluidic devices for handling of sub-micrometer particles. However, the streaming patterns observed in experiments can be of complicated and non-intuitive character, and therefore, experiments, and device optimization are often carried out in a trial-and-error manner. To overcome this obstacle, we classify acoustic streaming based on our recently developed theory of acoustic streaming. Using this theory we have shown that acoustic streaming is driven partly by Reynolds stresses in the bulk and partly by a slip-velocity condition at the walls due to Reynolds stresses in the acoustic boundary layers. Hence, in our classification, we distinguish between boundary-layer-driven and bulk-driven streaming. For boundary-layer-driven streaming at resonance, we classify the two physically relevant limits of parallel and perpendicular acoustics as well as the intermediate range. For bulk-driven streaming we find that the acoustic intensity vector plays a central role, and that this quantity can give rise to a strong bulk-driven streaming, if the acoustic fields have large angular momentum. In this context, we analyze mechanisms that can lead to rotating resonant modes in acoustic microchannels.Acoustic streaming is a nonlinear phenomenon that plays an essential role in microscale acoustofluidic devices for handling of sub-micrometer particles. However, the streaming patterns observed in experiments can be of complicated and non-intuitive character, and therefore, experiments, and device optimization are often carried out in a trial-and-error manner. To overcome this obstacle, we classify acoustic streaming based on our recently developed theory of acoustic streaming. Using this theory we have shown that acoustic streaming is driven partly by Reynolds stresses in the bulk and partly by a slip-velocity condition at the walls due to Reynolds stresses in the acoustic boundary layers. Hence, in our classification, we distinguish between boundary-layer-driven and bulk-driven streaming. For boundary-layer-driven streaming at resonance, we classify the two physically relevant limits of parallel and perpendicular acoustics as well as the intermediate range. For bulk-driven streaming we find that the aco...
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共振时声流的不同来源
声流是一种非线性现象,在处理亚微米颗粒的微尺度声流控装置中起着至关重要的作用。然而,在实验中观察到的流模式可能是复杂的和非直观的特征,因此,实验和设备优化通常以试错的方式进行。为了克服这一障碍,我们根据我们最近发展的声流理论对声流进行了分类。利用这一理论,我们已经证明,声流部分是由体内的雷诺应力驱动的,部分是由声边界层中雷诺应力引起的壁面滑移速度条件驱动的。因此,在我们的分类中,我们区分了边界层驱动和批量驱动的流。对于边界层驱动的共振流,我们将两个物理上相关的极限分为平行和垂直声学以及中间范围。对于体驱动流,我们发现声强矢量起着核心作用,如果声场具有较大的角动量,则声强矢量可以产生强大的体驱动流。在这种情况下,我们分析了在声学微通道中导致旋转谐振模式的机制。声流是一种非线性现象,在处理亚微米颗粒的微尺度声流控装置中起着至关重要的作用。然而,在实验中观察到的流模式可能是复杂的和非直观的特征,因此,实验和设备优化通常以试错的方式进行。为了克服这一障碍,我们根据我们最近发展的声流理论对声流进行了分类。利用这一理论,我们已经证明,声流部分是由体内的雷诺应力驱动的,部分是由声边界层中雷诺应力引起的壁面滑移速度条件驱动的。因此,在我们的分类中,我们区分了边界层驱动和批量驱动的流。对于边界层驱动的共振流,我们将两个物理上相关的极限分为平行和垂直声学以及中间范围。对于大容量驱动的流,我们发现aco…
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