Reciprocal swimming at intermediate Reynolds number

Derr, N. J.; Dombrowski, Thomas; Rycroft, Chris H.; Klotsa, Daphne

doi:10.1017/jfm.2022.873

Cited by 5 publications

(5 citation statements)

References 63 publications

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“…We found a similar cancelation in the mean swimming velocity of a deforming sphere 19,30 . The cancelation was found also for the mean swimming velocity of an oscillating two-sphere, as shown by Derr et al 31 . The first term in the expansion (6.13) for the moment K 2 (s) and in the expansion (6.14) for the moment M 2 (s) is equivalent to the result at high frequency found by Riley 8 and verified by Spelman and Lauga 14 .…”

Section: Outer Regionsupporting

confidence: 71%

“…It shows an interesting dependence on the scale parameter s = a ωρ/2η, with a flow reversal at the critical value s 0 = 2.85632. Clearly this will have drastic effects in the two-body problem, as shown in the analysis of the two-sphere swimming problem by Derr et al 31 . In particular we expect that the reversal of swim direction seen by Dombrowski et al 32 is related to the flow reversal of the single sphere steady streaming flow.…”

Section: Discussionmentioning

confidence: 99%

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Transition in steady streaming and pumping caused by a sphere oscillating in a viscous incompressible fluid

Felderhof

2023

Physics of Fluids

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The steady streaming flow pattern caused by a no-slip sphere oscillating in an unbounded viscous incompressible fluid is calculated exactly to second order in the amplitude. The pattern depends on a dimensionless scale number, determined by sphere radius, frequency of oscillation, and kinematic viscosity of the fluid. At a particular value of the scale number there is a transition with a reversal of flow. The analytical solution of the flow equations is based on a set of antenna theorems. The flow pattern consists of a boundary layer and an adjacent far-field of long range, falling off with the inverse square distance from the center of the sphere. The boundary layer becomes thin in the limit where inertia dominates over viscosity. The system acts as a pump operating in two directions, depending on the scale number. The efficiency of the pump is estimated from a comparison of the rate of flow with the rate of dissipation.

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Section: Outer Regionsupporting

confidence: 71%

Section: Discussionmentioning

confidence: 99%

Transition in steady streaming and pumping caused by a sphere oscillating in a viscous incompressible fluid

Felderhof

2023

Physics of Fluids

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“…This finding was confirmed by Nadal & Michelin (2020) and Derr et al. (2022). Interestingly, Lippera et al.…”

Section: Introductionsupporting

confidence: 70%

“…Collis, Chakraborty & Sader (2017 subsequently studied the motion of a general asymmetric particle at arbitrary frequency, and showed that the propulsion direction reverses at a critical frequency. This finding was confirmed by Nadal & Michelin (2020) and Derr et al (2022). Interestingly, Lippera et al (2019) proved that to first-order in particle non-sphericity, translational oscillations alone cannot generate propulsion; contrary to Nadal & Lauga (2014).…”

Section: Introductionmentioning

confidence: 91%

The propulsion direction of nanoparticles trapped in an acoustic field

Li,

Nunn,

Brumley

et al. 2024

J. Fluid Mech.

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Solid particles trapped in an acoustic standing wave have been observed to undergo propulsion. This phenomenon has been attributed to the generation of a steady streaming flow, with a reversal in the propulsion direction at a distinct frequency. We explain the mechanism underlying this reversal by considering the canonical problem of a sphere executing oscillatory rotation in an unbounded fluid that undergoes rectilinear oscillation; these two oscillations occur at identical frequency but with an arbitrary phase difference. Two distinct bifurcations in the flow field occur: (1) a stagnation point first forms with increasing frequency, which (2) splits into a saddle node and a vortex centre. Reversal in the propulsion direction is driven by reversal in the flow far from the sphere, which coincides with the second bifurcation. This flow is identified with that of a Stokeslet whose strength is the net force exerted on the particle, which has implications for studying the flow field around particles of non-spherical geometries and for modelling suspensions of particles in acoustic fields.

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“…Therefore, noninertial swimming microorganisms have evolved alternative strategies to propel themselves forward. Among these strategies is the exploitation of drag anisotropy, achieved through a series of time-irreversible motions ( 4 ). One well-known and widely studied example is the flagellar swimming of Escherichia coli , which has a single anterior flagellum, a rotary joint, and a motor to rotate the flagellum ( 5 , 6 ).…”

mentioning

confidence: 99%

Non-Stokesian dynamics of magnetic helical nanoswimmers under confinement

Fazeli,

Thakore,

Ala-Nissila

et al. 2024

PNAS Nexus

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Electromagnetically propelled helical nanoswimmers offer great potential for nanorobotic applications. Here, the effect of confinement on their propulsion is characterized using lattice-Boltzmann simulations. Two principal mechanisms give rise to their forward motion under confinement: 1) pure swimming, and 2) the thrust created by the differential pressure due to confinement. Under strong confinement, they face greater rotational drag, but display a faster propulsion for fixed driving frequency in agreement with experimental findings. This is due to the increased differential pressure created by the boundary walls when they are sufficiently close to each other and the particle. Two new analytical relations are presented: 1) for predicting the swimming speed of an unconfined particle as a function of its angular speed and geometrical properties, and 2) an empirical expression to accurately predict the propulsion speed of a confined swimmer as a function of the degree of confinement and its unconfined swimming speed. At low driving frequencies and degrees of confinement, the systems retain the expected linear behavior consistent with the predictions of the Stokes equation. However, as the driving frequency and/or the degree of confinement increase, their impact on propulsion leads to increasing deviations from the Stokesian regime and emergence of nonlinear behavior.

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Reciprocal swimming at intermediate Reynolds number

Cited by 5 publications

References 63 publications

Transition in steady streaming and pumping caused by a sphere oscillating in a viscous incompressible fluid

Transition in steady streaming and pumping caused by a sphere oscillating in a viscous incompressible fluid

The propulsion direction of nanoparticles trapped in an acoustic field

Non-Stokesian dynamics of magnetic helical nanoswimmers under confinement

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