Bulk and interfacial modes of instability in channel flow of thixotropic-viscoelasto-plastic fluids with shear-banding

We carry out a linear stability analysis of the generalised BMP model, which incorporates the shear-banding phenomenon into flows of thixotropic-viscoelasto-plastic fluids: common behaviours observed in wormlike micellar solutions. We introduce a new dimensionless parameter governing shear-banding,...

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Bibliographic Details
Published in:Journal of non-Newtonian fluid mechanics 2020-10, Vol.284, p.104357, Article 104357
Main Authors: Castillo, Hugo A., Wilson, Helen J.
Format: Article
Language:English
Subjects:
BMP model
Bulk instabilities
Channel flow
Computational fluid dynamics
Edge dislocations
Flow stability
Fluid flow
Interface stability
Interfacial instabilities
Oldroyd-B model
Parameters
Planar Poiseuille flow
Plastic properties
Plasticity
Pressure-driven channel flow
Relaxation time
Shear bands
Shear-banding
Stability Analysis
Thixotropy
Viscoelasticity
Worm-like micellar solutions
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Summary:We carry out a linear stability analysis of the generalised BMP model, which incorporates the shear-banding phenomenon into flows of thixotropic-viscoelasto-plastic fluids: common behaviours observed in wormlike micellar solutions. We introduce a new dimensionless parameter governing shear-banding, and find that when a flow is unstable in the absence of shear-banding, this parameter has a stabilising effect. Above a critical value of the shear-banding parameter, shear bands appear in the flow gradient direction. Here two different modes of instability are observed: a bulk mode (which is the same as that seen in the absence of shear banding) and an interfacial mode. We found that the former dominates over the latter at low values of the shear-banding parameter, but the interfacial instability becomes dominant at very high values of the parameter. In particular, the interfacial modes are more unstable in flows where the low shear band has almost constant viscosity. The two modes of instability depend on different material timescales: interfacial modes become more dangerous if the interface location is near the channel wall, which is seen when the structural relaxation time is much larger than that of plasticity, while bulk modes (as seen in previous work) are highly unstable if the timescale of viscoelasticity is much longer than both those of plasticity and thixotropy. •We study channel-flow instabilities using the generalised Bautista–Manero–Puig model.•A dimensionless parameter governing shear-banding is introduced.•Bulk and interfacial modes follow different material time-scale conditions.•Bulk instability is seen when viscoelastic effects dominate.•Interfacial modes dominate when the interface location is near the channel wall.
ISSN:0377-0257
1873-2631
DOI:10.1016/j.jnnfm.2020.104357