Boundary element methods for particles and microswimmers in a linear viscoelastic fluid

• Published in: Journal of fluid mechanics Vol. 831; pp. 228 - 251
• Main Authors: Ishimoto, Kenta, Gaffney, Eamonn A.
• Format: Journal Article
• Language: English
• Published: Cambridge, UK Cambridge University Press 25.11.2017
• Subjects: Amplitude; Boundary element method; Computational fluid dynamics; Deborah number; Deformation; Fluids; Frameworks; Integral equations; Interactions; Magnetic field; Magnetic fields; Mathematical analysis; Maxwell fluids; Meshing; Motility; Partial differential equations; Particle interactions; Physiology; Rheological properties; Rheology; Singularities; Sperm; Spermatozoa; Stokes law (fluid mechanics); Studies; Swimming; Theory; Trajectories; Velocity; Viscoelastic fluids; Viscoelasticity; biological fluid dynamics; boundary integral methods; viscoelasticity
• ISSN: 0022-1120; 1469-7645
• DOI: 10.1017/jfm.2017.636

The consideration of viscoelasticity within fluid dynamical boundary element methods has traditionally required meshing over the whole flow domain. In turn, a major advantage of the boundary element method is lost, namely the need to consider only surface boundary integrals. Here, using a generalised reciprocal relation and viscoelastic force singularities, a boundary element method is developed for linear viscoelastic flows. We proceed to explore finite-deformation microswimming in a linear Maxwell fluid. We firstly deduce a finite-amplitude generalisation of a previously reported result that the flow field is unchanged between a Newtonian and linear Maxwell fluid for prescribed small-amplitude deformations. Hence Purcell’s theorem holds for a linear Maxwell fluid. We proceed to consider deformation swimming in a linear Maxwell fluid given an external forcing. Boundary scattering trajectories for an exemplar squirmer approaching a surface are observed to exhibit a weak dependence on the Deborah number, while the trajectories of a sperm and monotrichous bacterium near a surface are predicted to be essentially unaffected at moderate Deborah number. In turn, the latter supports the common simplification of using Newtonian Stokes flows for studying flagellate swimming in linear Maxwell media. In addition, the motion of a magnetic helix under the influence of an external magnetic field is considered, and highlights that linear viscoelasticity can significantly impact the propagation of the helix, in turn demonstrating that even linear rheology is important to consider for forced swimmers. Finally, the presented framework requires minimalistic adjustments to Newtonian boundary element codes, enabling rapid implementation, and is more generally applicable, for instance to studies of particle interactions in active linear rheology on the microscale.