Pairwise interactions in inertially driven one-dimensional microfluidic crystals
Author(s)
Roper, Marcus; Hood, Kaitlyn Tuley
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In microfluidic devices, inertia drives particles to focus on a finite number of inertial focusing streamlines. Particles on the same streamline interact to form one-dimensional microfluidic crystals (or “particle trains”). Here we develop an asymptotic theory to describe the pairwise interactions underlying the formation of a one-dimensional crystal. Surprisingly, we show that particles assemble into stable equilibria, analogous to the motion of a damped spring. The damping of the spring is due to inertial focusing forces, and the spring force arises from the interplay of viscous particle-particle and particle-wall interactions. The equilibrium spacing can be represented by a quadratic function in the particle size and therefore can be controlled by tuning the particle radius.
Date issued
2018-09Department
Massachusetts Institute of Technology. Department of Mechanical EngineeringJournal
Physical Review Fluids
Publisher
American Physical Society
Citation
Hood, Kaitlyn, and Marcus Roper. “Pairwise Interactions in Inertially Driven One-Dimensional Microfluidic Crystals.” Physical Review Fluids, vol. 3, no. 9, Sept. 2018. © 2018 American Physical Society
Version: Final published version
ISSN
2469-990X