Issue 2, 2014

Theory and experiment on particle trapping and manipulation via optothermally generated bubbles

Abstract

We present a theoretical analysis and experimental demonstration of particle trapping and manipulation around optothermally generated bubbles. We show that a particle located within 500 μm of a surface bubble can be attracted towards a bubble by drag force resulting from a convective flow. Once the particle comes in contact with the bubble's surface, a balance between surface tension forces and pressure forces traps the particle on the bubble surface, allowing the particle to move with the bubble without detaching. The proposed mechanism is confirmed by computational fluid dynamics simulations, force calculations, and experiments. Based on this mechanism, we experimentally demonstrated a novel approach for manipulating microparticles via optothermally generated bubbles. Using this approach, randomly distributed microparticles were effectively collected and carried to predefined locations. Single particles were also manipulated along prescribed trajectories. This bubble-based particle trapping and manipulation technique can be useful in applications such as micro assembly, particle concentration, and high-precision particle separation.

Graphical abstract: Theory and experiment on particle trapping and manipulation via optothermally generated bubbles

Supplementary files

Article information

Article type
Paper
Submitted
22 Jun 2013
Accepted
09 Oct 2013
First published
26 Nov 2013

Lab Chip, 2014,14, 384-391

Theory and experiment on particle trapping and manipulation via optothermally generated bubbles

C. Zhao, Y. Xie, Z. Mao, Y. Zhao, J. Rufo, S. Yang, F. Guo, J. D. Mai and T. J. Huang, Lab Chip, 2014, 14, 384 DOI: 10.1039/C3LC50748C

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