Analysis of the shear thickening behavior of a fumed silica suspension using QL-LAOS approach

•Dependence with shear of the shear-thickening microstructure of fumed silica suspensions.•Validation of QL-LAOS approach for testing shear-thickening suspensions.•Shear-thickening microstructure evolves with shear from big/few to small/many hydroclusters. The feasibility of applying quasi-linear la...

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Bibliographic Details
Published in:Journal of non-Newtonian fluid mechanics 2025-01, Vol.335, p.105355, Article 105355
Main Authors: Fernández-Díaz, E., Rubio-Hernández, F.J., Velázquez-Navarro, J.F.
Format: Article
Language:English
Subjects:
Fumed silica suspension
QL-LAOS
Shear-thickening
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Summary:•Dependence with shear of the shear-thickening microstructure of fumed silica suspensions.•Validation of QL-LAOS approach for testing shear-thickening suspensions.•Shear-thickening microstructure evolves with shear from big/few to small/many hydroclusters. The feasibility of applying quasi-linear large amplitude oscillatory shear (QL-LAOS) approach to a shear thickening (ST) fumed silica suspension was tested. While the characteristic time has been used as the parameter for the original QL-LAOS analysis of shear thinning fluids, we obtained that a description based upon increasing stiffness is more appropriate for ST fumed silica suspensions. Very low (≤1.5) third to first harmonics ratio were obtained indicating the need of alternative criteria to identify QL-LAOS behavior in ST suspensions. Consequently, a method based upon the best fit of an ellipse to the experimental Lissajous-Bowditch curves was proposed. Compliances were obtained from areas of viscous and elastic fitted ellipses. The dependence of the material functions obtained by using a Jeffrey´s mechanical viscoelastic framework with angular frequency supports the idea of ST microstructure evolves by increasing with shear the number of small hydroclusters.
ISSN:0377-0257
DOI:10.1016/j.jnnfm.2024.105355