(372d) Fingering Instability of a Suspension Film Spreading on a Spinning Disk | AIChE

(372d) Fingering Instability of a Suspension Film Spreading on a Spinning Disk

Authors 

Sahoo, S. - Presenter, CSIR-National Chemical Laboratory
Doshi, P., Worldwide Research and Development, Pfizer Inc.
Orpe, A. V., National Chemical Laboratory
We have experimentally investigated the spreading of a suspension drop when rotated atop a spinning disc using flow visualization techniques. The suspension is created from 53â??106 micron glass beads suspended in a low viscosity, partially wetting Newtonian liquid having same density as the glass beads. The suspension drop (of differing particle volume fractions) is placed centrally on a horizontal disc and the disc is then rotated at a desired speed. The spreading behavior is captured using a high speed camera and the acquired images are analyzed to find the edges of the spreading drop. For all particle volume fractions (Ï?p), the suspension drop spreads upto a critical radius, before the contact line (drop edge) develops instabilities which further grow into fingers. The dependence on Ï?p is, however, found to be quite remarkable. The critical radius for the onset of instability shows an increase with increase in the particle fraction (Ï?p) before decreasing slightly at the highest value of Ï?p studied, while the instability wavelength (λ) exhibits a non-monotonic dependence. The value of λ is close to that for a partially wetting liquid at lower Ï?p, it decreases with increasing Ï?p to a minimum before increasing again at largest Ï?p. The non-monotonic trends observed for λ are discussed in light of the linear stability analysis of thin film equations derived for suspensions by Cook et al., [1] and Balmforth et al., [2].

References:

[1] B. P. Cook, O. Alexandrov, and A. L. Bertozzi, â??Linear stability of particle-laden thin films,â? Eur. Phys. J. Special Topics 166, 77 (2009).

[2] N. Balmforth, S. Ghadge, and T. Myers, â??Surface tension driven fingering of a viscoplastic film,â? J. Non-Newtonian Fluid Mech. 142, 143 (2007).