Characterization of capillary rise dynamics in parallel micro V-grooves

Abstract

Capillary rise in micro grooves shows its widespread applications in microfluidics in a wide range of areas, such as heat transfer devices, fluids management, polymer films and many other fields. The present study examines the capillary rise in copper micro V-grooves using two liquid acetone and ethanol. An infrared (IR) thermal imaging method was utilized to register the liquid front. Different groove samples with five groove depths from 500μm to 850μm and four groove widths ranged from 400μm to 600μm were characterized. The experimental results were compared to the theoretical models to assess the flow kinetics of capillary rise. It was found that the capillary rise in these micro V-grooves firstly followed the Washburn relation (h(t)∼t1/2), then was governed by the h(t)∼t1/3 as similar as the dynamics of liquid rise in corners or wedges, and finally exhibited the exponential dynamics. The one-third powder law should be modified by incorporation of the contact angle term, whereas the groove geometry showed negligible effect on this kinetics.