Djellouli Adel, Marmottant Philippe, Djeridi Henda, Quilliet Catherine, Coupier Gwennou
Université Grenoble Alpes, CNRS, LIPhy, F-38000 Grenoble, France.
Université Grenoble Alpes, Grenoble INP, CNRS, LEGI, F-38000 Grenoble, France.
Phys Rev Lett. 2017 Dec 1;119(22):224501. doi: 10.1103/PhysRevLett.119.224501. Epub 2017 Nov 27.
Microswimmers, and among them aspirant microrobots, generally have to cope with flows where viscous forces are dominant, characterized by a low Reynolds number (Re). This implies constraints on the possible sequences of body motion, which have to be nonreciprocal. Furthermore, the presence of a strong drag limits the range of resulting velocities. Here, we propose a swimming mechanism which uses the buckling instability triggered by pressure waves to propel a spherical, hollow shell. With a macroscopic experimental model, we show that a net displacement is produced at all Re regimes. An optimal displacement caused by nontrivial history effects is reached at intermediate Re. We show that, due to the fast activation induced by the instability, this regime is reachable by microscopic shells. The rapid dynamics would also allow high-frequency excitation with standard traveling ultrasonic waves. Scale considerations predict a swimming velocity of order 1 cm/s for a remote-controlled microrobot, a suitable value for biological applications such as drug delivery.
微型游动器,其中包括有望成为微型机器人的类型,通常必须应对粘性力占主导的流体,其特征是雷诺数(Re)较低。这意味着对身体运动可能序列的限制,这些序列必须是非互易的。此外,强大的阻力限制了最终速度的范围。在此,我们提出一种游动机制,该机制利用压力波引发的屈曲不稳定性来推动一个球形空心壳。通过一个宏观实验模型,我们表明在所有雷诺数 regime 下都会产生净位移。在中等雷诺数时,由于非平凡历史效应会达到最佳位移。我们表明,由于不稳定性引起的快速激活,微观壳层可以达到这个 regime。快速动力学也将允许用标准行波超声波进行高频激发。尺度考量预测,对于一个遥控微型机器人,其游动速度约为1厘米/秒,这对于诸如药物递送等生物应用来说是一个合适的值。
