Slender body theories for rotating filaments

Slender fibres are ubiquitous in biology, physics and engineering, with prominent examples including bacterial flagella and cytoskeletal fibres. In this setting, slender body theories (SBTs), which give the resistance on the fibre asymptotically in its slenderness $\epsilon$, are useful tools for bo...

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Bibliographic Details
Published in:Journal of fluid mechanics 2022-12, Vol.952, Article A5
Main Authors: Maxian, Ondrej, Donev, Aleksandar
Format: Article
Language:English
Subjects:
Angular velocity
Approximation
Asymptotic properties
Biology
Coupling
Cross-sections
Cytoskeleton
Dynamics
Empirical equations
Fibers
Filaments
Flagella
Geometry
Integral equations
JFM Papers
Partial differential equations
Physics
Regularization methods
Rotating bodies
Rotation
Singularity (mathematics)
Slender bodies
Surveying
Theories
Torque
Translation
Velocity
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Summary:Slender fibres are ubiquitous in biology, physics and engineering, with prominent examples including bacterial flagella and cytoskeletal fibres. In this setting, slender body theories (SBTs), which give the resistance on the fibre asymptotically in its slenderness $\epsilon$, are useful tools for both analysis and computations. However, a difficulty arises when accounting for twist and cross-sectional rotation: because the angular velocity of a filament can vary depending on the order of magnitude of the applied torque, asymptotic theories must give accurate results for rotational dynamics over a range of angular velocities. In this paper, we first survey the challenges in applying existing SBTs, which are based on either singularity or full boundary integral representations, to rotating filaments, showing in particular that they fail to consistently treat rotation–translation coupling in curved filaments. We then provide an alternative approach which approximates the three-dimensional dynamics via a one-dimensional line integral of Rotne–Prager–Yamakawa regularized singularities. While unable to accurately resolve the flow field near the filament, this approach gives a grand mobility with symmetric rotation–translation and translation–rotation coupling, making it applicable to a broad range of angular velocities. To restore fidelity to the three-dimensional filament geometry, we use our regularized singularity model to inform a simple empirical equation which relates the mean force and torque along the filament centreline to the translational and rotational velocity of the cross-section. The single unknown coefficient in the model is estimated numerically from three-dimensional boundary integral calculations on a rotating, curved filament.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2022.869