Efficient shapes for microswimming: From three-body swimmers to helical flagella
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2017-02-27
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Abstract
We combine a general formulation of microswimmer equations of motion with a numerical beadshell model to calculate the hydrodynamic interactions with the fluid, from which the swimming speed, power, and efficiency are extracted. From this framework, a generalized Scallop theorem emerges. The applicability to arbitrary shapes allows for the optimization of the efficiency with respect to the swimmer geometry.We apply this scheme to “three-body swimmers” of various shapes and find that the efficiency is characterized by the single-body friction coefficient in the long-arm regime, while in the short-arm regime the minimal approachable distance becomes the determining factor. Next, we apply this scheme to a biologically inspired set of swimmers that propel using a rotating helical flagellum. Interestingly, we find two distinct optimal shapes, one of which is fundamentally different from the shapes observed in nature (e.g., bacteria).
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Bet, B P, Boosten, G, Dijkstra, M & van Roij, R H H G 2017, 'Efficient shapes for microswimming : From three-body swimmers to helical flagella', Journal of Chemical Physics, vol. 146, no. 8, 084904. https://doi.org/10.1063/1.4976647