Rapid and controllable digital microfluidic heating by surface acoustic waves

Abstract

Fast and controllable surface acoustic wave (SAW) driven digital microfluidic temperature changes are demonstrated. Within typical operating conditions, the direct acoustic heating effect is shown to lead to a maximum temperature increase of about 10 °C in microliter water droplets. The importance of decoupling droplets from other on-chip heating sources is demonstrated. Acoustic-heating-driven temperature changes reach a highly stable steady-state value in ≈3 s, which is an order of magnitude faster than previously published. This rise time can even be reduced to ≈150 ms by suitably tailoring the applied SAW-power excitation profile. Moreover, this fast heating mechanism can lead to significantly higher temperature changes (over 40 °C) with higher viscosity fluids and can be of much interest for on-chip control of biological and/or chemical reactions. Fast and controllable surface acoustic wave (SAW) driven digital microfluidic temperature changes are demonstrated. Small temperature changes in typical SAW microfluidic conditions and the possibility for rapid and controllable high temperature changes, for use with lab-on-a-chip devices, are shown.