Affiliation:
1. School of Engineering RMIT University Melbourne VIC 3000 Australia
2. Baker Heart and Diabetes Institute Melbourne VIC 3004 Australia
3. Department of Cardiometabolic Health The University of Melbourne Parkville VIC 3010 Australia
Abstract
AbstractHere, the generation of dynamic vortices across microscale barriers using the tube oscillation mechanism is demonstrated. Using a combination of high‐speed imaging and computational flow dynamics, the cyclic formation, expansion, and collapse of vortices are studied. The dynamics of vortices across circular , triangular, and blade‐shape barriers are investigated at different tube oscillation frequencies. The formation of an array of synchronous vortices across parallel blade‐shaped barriers is demonstrated. The transient flows caused by these dynamic vortex arrays are harnessed for the rapid and efficient mixing of blood samples . A circular barrier scribed with a narrow orifice on its shoulder is used to facilitate the injection of liquid into the microfluidic channel, and its rapid mixing with the main flow through the dynamic vortices generated across the barrier. This approach facilitates the generation of vortices with desirable configurations, sizes, and dynamics in a highly controllable, programmable, and predictable manner while operating at low static flow rates.
Funder
Australian Research Council
National Health and Medical Research Council