1999
DOI: 10.1103/physrevlett.82.1590
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Self-Organized Beating and Swimming of Internally Driven Filaments

Abstract: We study a simple two-dimensional model for motion of an elastic filament subject to internally generated stresses and show that wavelike propagating shapes which can propel the filament can be induced by a self-organized mechanism via a dynamic instability. The resulting patterns of motion do not depend on the microscopic mechanism of the instability but only of the filament rigidity and hydrodynamic friction. Our results suggest that simplified systems, consisting only of molecular motors and filaments, coul… Show more

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Cited by 198 publications
(232 citation statements)
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“…This equation was also derived in earlier work by Machin in the context of wave propagation in the flagella of swimming microorganisms [16,17]. A similar theoretical treatment was proposed as a simple model of the sliding filament model of eukaryotic axonemal beating by coupling the elasto-hydrodynamics problem with models for the behavior of active molecular motors [18,19].…”
Section: Introductionmentioning
confidence: 91%
See 1 more Smart Citation
“…This equation was also derived in earlier work by Machin in the context of wave propagation in the flagella of swimming microorganisms [16,17]. A similar theoretical treatment was proposed as a simple model of the sliding filament model of eukaryotic axonemal beating by coupling the elasto-hydrodynamics problem with models for the behavior of active molecular motors [18,19].…”
Section: Introductionmentioning
confidence: 91%
“…This equation was also derived in earlier work by Machin in the context of wave propagation in the flagella of swimming microorganisms [16,17]. A similar theoretical treatment was proposed as a simple model of the sliding filament model of eukaryotic axonemal beating by coupling the elasto-hydrodynamics problem with models for the behavior of active molecular motors [18,19].The main features of this problem have been successfully exploited experimentally to measure the bending modulus of biopolymers (actin filaments and microtubules), either using thermal fluctuations [20] or using an active actuation [21,22]. Related studies include the dynamics of magnetic filaments [23][24][25], the three-dimensional actuation and *…”
mentioning
confidence: 91%
“…We study competition between three processes: twist injection at the rotated end, twist diffusion, and writhing. Analytical and numerical methods reveal two dynamical regimes of motion: twirling, in which the straight but twisted rod rotates about its centerline, and whirling, in which the centerline of the rod writhes and crankshafts around the rotation axis in a steady state.This work is a natural outgrowth of recent studies of forced elastica in the plane [10,11], and dynamic twistbend coupling [12][13][14]. The balance considered between elastic and viscous stresses complements that between elasticity and inertia in the inviscid limit (as in whirling shafts [15,16]), where twist waves propagate [15,17].…”
mentioning
confidence: 99%
“…This work is a natural outgrowth of recent studies of forced elastica in the plane [10,11], and dynamic twistbend coupling [12][13][14]. The balance considered between elastic and viscous stresses complements that between elasticity and inertia in the inviscid limit (as in whirling shafts [15,16]), where twist waves propagate [15,17].…”
mentioning
confidence: 99%
“…From a fundamental perspective, the transport of microscopic objects in a liquid medium poses the appealing challenge to find an adequate swimming strategy due to the negligible role of inertial force compared to viscous one. At low Reynolds number the Navier-Stokes equations become time reversible [1], and any strategy based on reciprocal motion, i.e., a motion composed by symmetric backward and forward displacements, will fail to produce net propulsion [2].Facing this challenge, the last few years have witnessed the theoretical propositions of several suitable geometries and procedures to propel micromachines in viscous fluids [3][4][5][6][7][8][9]. Parallel advances in miniaturization have led to the generation of new classes of chemically powered [10,11] or externally actuated [12][13][14][15] prototypes with exciting applications in emerging fields such as microsurgery [16,17] or lab-on-a-chip technology [18,19].…”
mentioning
confidence: 99%