English

Static response of deformable microchannels: A comparative modelling study

Fluid Dynamics 2020-07-10 v4 Soft Condensed Matter

Abstract

We present a comparative modelling study of fluid-structure interactions in microchannels. Through a mathematical analysis based on plate theory and the lubrication approximation for low-Reynolds-number flow, we derive models for the flow rate-pressure drop relation for long shallow microchannels with both thin and thick deformable top walls. These relations are tested against full three-dimensional two-way-coupled fluid-structure interaction simulations. Three types of microchannels, representing different elasticity regimes and having been experimentally characterized previously, are chosen as benchmarks for our theory and simulations. Good agreement is found in most cases for the predicted, simulated and measured flow rate-pressure drop relationships. The numerical simulations performed allow us to also carefully examine the deformation profile of the top wall of the microchannel in any cross section, showing good agreement with the theory. Specifically, the prediction that span-wise displacement in a long shallow microchannel decouples from the flow-wise deformation is confirmed, and the predicted scaling of the maximum displacement with the hydrodynamic pressure and the various material and geometric parameters is validated.

Keywords

Cite

@article{arxiv.1709.03002,
  title  = {Static response of deformable microchannels: A comparative modelling study},
  author = {Tanmay C. Shidhore and Ivan C. Christov},
  journal= {arXiv preprint arXiv:1709.03002},
  year   = {2020}
}

Comments

19 pages, 14 figures, IOP style; submitted to a special issue of Journal of Physics: Condensed Matter on "Physics of integrated microfluidics"; v2 corrects problem with bounding box on fig. 9; v3 minor revisions; v4 corrects typos listed in corrigendum to published paper

R2 v1 2026-06-22T21:38:02.087Z