Motion of an active bent rod with an articulating hinge: exploring mechanical and chemical modes of swimming

Raj, Ritu R.; Ganguly, Arkava; Becker, Cora; Shields, C. Wyatt; Gupta, Ankur

doi:10.3389/fphy.2023.1307691

Cited by 2 publications

(1 citation statement)

References 110 publications

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“…However, these trajectories can be further controlled by combining two different modes of swimming. In Raj et al (2023a), the authors investigated the combination of chemical and mechanical modes of swimming simultaneously, and noted that even reciprocal strokes yield nonreciprocal displacement when both modes are employed simultaneously. Similar investigations with other modes of activation such as electric fields and magnetic fields could provide improved control over particle trajectories (Lee et al, 2023a).…”

Section: Future Opportunitiesmentioning

confidence: 99%

Diffusiophoresis: a novel transport mechanism - fundamentals, applications, and future opportunities

Ganguly,

Alessio,

Gupta

2023

Front. Sens.

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Diffusiophoresis involves the movement of colloidal-scale entities in response to concentration gradients of a solute. It is broadly categorized into two types: passive and active diffusiophoresis. In passive diffusiophoresis, external concentration gradients drive the motion, while in active diffusiophoresis, the colloidal entity itself assists in generating the gradients. In this perspective, we delve into the fundamental processes underlying passive and active diffusiophoresis and emphasize how prevalent both kinds of diffusiophoresis are in colloidal and natural systems. In particular, we highlight the colloidal focusing feature in passive diffusiophoresis and discuss how it underpins the variety of experimental observations and applications such as low-cost zetasizers, water filtration, and biological pattern formation. For active diffusiophoresis, we emphasize the dependence of particle trajectory on its shape and surface heterogeneity, and discuss how this dictates the applications such as drug delivery, removal of microplastics, and self-repairing materials. Finally, we offer insights and ideas regarding future opportunities in diffusiophoresis.

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Section: Future Opportunitiesmentioning

confidence: 99%

Diffusiophoresis: a novel transport mechanism - fundamentals, applications, and future opportunities

Ganguly,

Alessio,

Gupta

2023

Front. Sens.

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Unified mobility expressions for externally driven and self-phoretic propulsion of particles

Ganguly,

Roychowdhury,

Gupta

2024

J. Fluid Mech.

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The mobility of externally driven phoretic propulsion of particles is evaluated by simultaneously solving the solute conservation equation, interaction potential equation and the modified Stokes equation. While accurate, this approach is cumbersome, especially when the interaction potential decays slowly compared with the particle size. In contrast to external phoresis, the motion of self-phoretic particles is typically estimated by relating the translation and rotation velocities with the local slip velocity. While this approach is convenient and thus widely used, it is only valid when the interaction decay length is significantly smaller than the particle size. Here, by taking inspiration from Brady (J. Fluid Mech., vol. 922, 2021, A10), which combines the benefits of two approaches, we reproduce their unified mobility expressions with arbitrary interaction potentials and show that these expressions can conveniently recover the well-known mobility relationships of external electrophoresis and diffusiophoresis for arbitrary double-layer thickness. Additionally, we show that for a spherical microswimmer, the derived expressions relax to the slip velocity calculations in the limit of the thin interaction length scales. We also employ the derived mobility expressions to calculate the velocities of an autophoretic Janus particle. We find that there is significant dampening in the translation velocity even when the interaction length is an order of magnitude larger than the particle size. Finally, we study the motion of a catalytically self-propelled particle, while it also propels due to external concentration gradients, and demonstrate how the two propulsion modes compete with each other.

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Motion of an active bent rod with an articulating hinge: exploring mechanical and chemical modes of swimming

Cited by 2 publications

References 110 publications

Diffusiophoresis: a novel transport mechanism - fundamentals, applications, and future opportunities

Diffusiophoresis: a novel transport mechanism - fundamentals, applications, and future opportunities

Unified mobility expressions for externally driven and self-phoretic propulsion of particles

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