Journal article
Diffusion enhancement in a laminar flow liquid by near-surface transport of superparamagnetic bead rows
Publication Details
Authors: | Holzinger, D.; Ehresmann, A. |
Publication year: | 2015 |
Journal: | Microfluidics and Nanofluidics |
Pages range : | 395-402 |
Volume number: | 19 |
Start page: | 395 |
End page: | 402 |
ISSN: | 1613-4982 |
eISSN: | 1613-4990 |
DOI-Link der Erstveröffentlichung: |
Abstract
An accurate computational fluid dynamic simulation model is presented to quantitatively elaborate parameter trends for optimum active mixing in a microfluidic device due to the domain wall movement assisted transport of superparamagnetic bead rows above a magnetic microstripe-patterned exchange bias layer system using ComsolMultiphysics. The presented simulation model is capable to study the effect of the microfluidic device length scales, the diffusive properties of the diluted species to be mixed and the applied movement scheme of the SPB rows for active mixing. The results show a remarkable increase in the mixing velocity for larger molecules with small molecular diffusion coefficients. Hence, this mixing technique seems to be promising for the implementation in biosensing applications for lab-on-a-chip devices.
An accurate computational fluid dynamic simulation model is presented to quantitatively elaborate parameter trends for optimum active mixing in a microfluidic device due to the domain wall movement assisted transport of superparamagnetic bead rows above a magnetic microstripe-patterned exchange bias layer system using ComsolMultiphysics. The presented simulation model is capable to study the effect of the microfluidic device length scales, the diffusive properties of the diluted species to be mixed and the applied movement scheme of the SPB rows for active mixing. The results show a remarkable increase in the mixing velocity for larger molecules with small molecular diffusion coefficients. Hence, this mixing technique seems to be promising for the implementation in biosensing applications for lab-on-a-chip devices.
Keywords
CFD simulations, Diffusion enhancement, DOWMAT, Exchange bias, Microfluid mixing, Particle transport