Controlling stability and transport of magnetic microswimmers by an external field

Koessel, Fabian R.; Jabbari-Farouji, Sara

doi:10.1209/0295-5075/125/28001

Cited by 12 publications

(12 citation statements)

References 65 publications

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“…This result intimately relates vanishing shear viscosity to the onset of collective motion, albeit only in infinite systems: CKT treats the driving flow as homogeneous and infinite and is thus insensitive to the size of the system. Moreover, with few exceptions (31,32), CKT studies of rheology to date have ignored interparticle interactions. Formulating a CKT in confinement properly is technically demanding.…”

Section: Current Theoriesmentioning

confidence: 99%

A combined rheometry and imaging study of viscosity reduction in bacterial suspensions

Martinez

Clément

Arlt

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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Suspending self-propelled “pushers” in a liquid lowers its viscosity. We study how this phenomenon depends on system size in bacterial suspensions using bulk rheometry and particle-tracking rheoimaging. Above the critical bacterial volume fraction needed to decrease the viscosity to zero, ϕc≈0.75%, large-scale collective motion emerges in the quiescent state, and the flow becomes nonlinear. We confirm a theoretical prediction that such instability should be suppressed by confinement. Our results also show that a recent application of active liquid-crystal theory to such systems is untenable.

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Section: Current Theoriesmentioning

confidence: 99%

A combined rheometry and imaging study of viscosity reduction in bacterial suspensions

Martinez

Clément

Arlt

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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“…For example, the magnetic alignment, combined with a micro-aerotactic swimming response, qualifies such micro-swimmers as a promising vector for targeted drug therapy [32]. Recently, it was proposed, on theoretical grounds, that a suspension of such magnetotactic bacteria could display original magneto-rheological properties [33,34], novel pattern formation [35] and hydrodynamic instabilities [36,37].…”

Section: Introductionmentioning

confidence: 99%

Magnetotactic bacteria in a droplet self-assemble into a rotary motor

et al. 2019

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From intracellular protein trafficking to large-scale motion of animal groups, the physical concepts driving the self-organization of living systems are still largely unraveled. Self-organization of active entities, leading to novel phases and emergent macroscopic properties, recently shed new light on these complex dynamical processes. Here we show that under the application of a constant magnetic field, motile magnetotactic bacteria confined in water-in-oil droplets self-assemble into a rotary motor exerting a torque on the external oil phase. A collective motion in the form of a large-scale vortex, reversable by inverting the field direction, builds up in the droplet with a vorticity perpendicular to the magnetic field. We study this collective organization at different concentrations, magnetic fields and droplet radii and reveal the formation of two torque-generating areas close to the droplet interface. We characterize quantitatively the mechanical energy extractable from this new biological and self-assembled motor.

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“…Theoretically it is shown that MTB might present original magnetorheological properties and present novel collective behavior. [ 378–381 ] Experimentally, the MTB were shown to behave as rotary motors in oil–water emulsions for example and therefore their behavior in complex medium is an open field. [ 382 ] In this line, taking into account that among MTB strains they have different properties and needs, the same diversity is most likely to be translated to different collective behaviors which if controllable are of interest for the field or robotics.…”

Section: Discussion and Future Workmentioning

confidence: 99%

Magnetic Actuation Methods in Bio/Soft Robotics

Ebrahimi

Cappelleri

et al. 2020

Adv Funct Materials

192

104

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In recent years, magnetism has gained an enormous amount of interest among researchers for actuating different sizes and types of bio/soft robots, which can be via an electromagnetic‐coil system, or a system of moving permanent magnets. Different actuation strategies are used in robots with magnetic actuation having a number of advantages in possible realization of microscale robots such as bioinspired microrobots, tetherless microrobots, cellular microrobots, or even normal size soft robots such as electromagnetic soft robots and medical robots. This review provides a summary of recent research in magnetically actuated bio/soft robots, discussing fabrication processes and actuation methods together with relevant applications in biomedical area and discusses future prospects of this way of actuation for possible improvements in performance of different types of bio/soft robots.

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Controlling stability and transport of magnetic microswimmers by an external field

Cited by 12 publications

References 65 publications

A combined rheometry and imaging study of viscosity reduction in bacterial suspensions

A combined rheometry and imaging study of viscosity reduction in bacterial suspensions

Magnetotactic bacteria in a droplet self-assemble into a rotary motor

Magnetic Actuation Methods in Bio/Soft Robotics

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