Bubble-induced damping in displacement-driven microfluidic flows

Author(s)

Lee, Jongho; Rahman, Faizur; Laoui, Tahar; Karnik, Rohit

Abstract

Bubble damping in displacement-driven microfluidic flows was theoretically and experimentally investigated for a Y-channel microfluidic network. The system was found to exhibit linear behavior for typical microfluidic flow conditions. The bubbles induced a low-pass filter behavior with a characteristic cutoff frequency that scaled proportionally with flow rate and inversely with bubble volume and exhibited a minimum with respect to the relative resistances of the connecting channels. A theoretical model based on the electrical circuit analogy was able to predict experimentally observed damping of fluctuations with excellent agreement. Finally, a flowmeter with high resolution (0.01 μL/min) was demonstrated as an application of the bubble-aided stabilization. This study may aid in the design of many other bubble-stabilized microfluidic systems.

Date issued

2012-08

URI

http://hdl.handle.net/1721.1/74169

Department

Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

Physical Review E

Publisher

American Physical Society

Citation

Lee, Jongho et al. “Bubble-induced Damping in Displacement-driven Microfluidic Flows.” Physical Review E 86.2 (2012). ©2012 American Physical Society

Version: Final published version

ISSN

1539-3755

1550-2376