Abstract
The conformations and dynamics of semiflexible filaments subject to a homogeneous external (gravitational) field, e.g., in a centrifuge, are studied numerically and analytically. The competition between hydrodynamic drag and bending elasticity generates new shapes and dynamical features. We show that the shape of a semiflexible filament undergoes instabilities as the external field increases. We identify two transitions that correspond to the excitation of higher bending modes. In particular, for strong fields the filament stabilizes in a non-planar shape, resulting in a sideways drift or in helical trajectories. For two interacting filaments, we find the same transitions, with the important consequence that the new non-planar shapes have an effective hydrodynamic repulsion, in contrast to the planar shapes which attract themselves even when their osculating planes are rotated with respect to each other. For the case of planar filaments, we show analytically and numerically that the relative velocity is not necessarily due to a different drag of the individual filaments, but to the hydrodynamic interactions induced by their shape asymmetry.
Highlights
Semiflexible filaments are fundamental constituents of microbiological systems, where microtubules and actin filaments serve as scaffolds for cellular structures and as routes to sustain and guide cellular transport systems.[1]
We focus on the full three-dimensional shape of one, two, and three semiflexible filaments sedimenting in a homogeneous external field
As a result of our numerical and analytical analysis, we find that the deformations confined to a plane become unstable with respect to normal perturbations at a threshold value B1* of the strength B of the external field, which is smaller than the threshold B2* where initial, transient W-shapes become excited, see Fig. 1
Summary
Semiflexible filaments are fundamental constituents of microbiological systems, where microtubules and actin filaments serve as scaffolds for cellular structures and as routes to sustain and guide cellular transport systems.[1]. A more complex dynamical behavior can be expected and is observed for semiflexible filaments when the curvature or stretching elasticity competes with the hydrodynamic interactions.[9,10,11] Single dragged semiflexible. We focus on the full three-dimensional shape of one, two, and three semiflexible filaments sedimenting in a homogeneous external field. As a result of our numerical and analytical analysis, we find that the deformations confined to a plane become unstable with respect to normal perturbations at a threshold value B1* of the strength B of the external field, which is smaller than the threshold B2* where initial, transient W-shapes become excited, see Fig. 1. The dynamical behavior is even more complex.[10] In particular, we show that two filaments (Fig. 1) attract each other, repel each other, or spin around the field depending on the intensity of the external field. The dynamics becomes unsteady at much weaker external field strength than expected from the two-filaments case
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