Flexible/Bendable Acoustofluidics Based on Thin-Film Surface Acoustic Waves on Thin Aluminum Sheets

In this paper, we explore the acoustofluidic performance of zinc oxide (ZnO) thin-film surface acoustic wave (SAW) devices fabricated on flexible and bendable thin aluminum (Al) foils/sheets with thicknesses from 50 to 1500 mu m. Directional transport of fluids along these flexible/bendable surfaces offers potential applications for the next generation of microfluidic systems, wearable biosensors and soft robotic control. Theoretical calculations indicate that bending under strain levels up to 3000 mu epsilon causes a small frequency shift and amplitude change (<0.3%) without degrading the acoustofluidic performance. Through systematic investigation of the effects of the Al sheet thickness on the microfluidic actuation performance for the bent devices, we identify the optimum thickness range to both maintain efficient microfluidic actuation and enable significant deformation of the substrate, providing a guide to design such devices. Finally, we demonstrate efficient liquid transportation across a wide range of substrate geometries including inclined, curved, vertical, inverted, and lateral positioned surfaces using a 200 mu m thick Al sheet SAW device.

Automated summary

The performance of zinc oxide (ZnO) thin-film surface acoustic wave (SAW) devices on flexible and bendable thin aluminum (Al) foils/sheets with various thicknesses was explored in this study. Theoretical calculations show that bending under strain levels up to 3000 mu epsilon causes minimal frequency shift and amplitude change, maintaining acoustofluidic performance. The study identified the optimal thickness range of the Al sheet for efficient microfluidic actuation and significant deformation of the substrate, providing a guide for device design. Efficient liquid transportation across a wide range of substrate geometries was demonstrated using a 200 mu m thick Al sheet SAW device.