Surface anchoring controls orientation of a microswimmer in nematic liquid crystal

Chi, Hai; Potomkin, Mykhailo; Zhang, Lei; Berlyand, Leonid; Aranson, Igor S.

doi:10.1038/s42005-020-00432-z

Cited by 21 publications

(22 citation statements)

References 39 publications

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“…If W > W crit , the pusher prefers to swim perpendicular to n ∞ . Similar results were obtained in [31] for the stable swimming direction of a single microswimmer in classical LC described by the Beris-Edwards model without conformation tensor C. Compared to the swimmer dynamics in non-viscoelastic nematics, the new finding here is that viscoelasticity affects the convergence rate of the swimmer's orientation to its stable swimming direction if χ < 0. A puller with weak planar anchoring whose preferred swimming direction is perpendicular to n ∞ rotates to its preferred swimming direction faster (see Figure 2(b)).…”

Section: Resultssupporting

confidence: 82%

“…In general, for a swimmer in LC, there are two preferred orientations: (i) a swimming direction favored due to the type of swimmer; (ii) another swimming direction favored due to the elongated shape of the swimmer together with the anchoring type. In the case when these two favored directions are different, critical behavior is found [31].…”

Section: Resultsmentioning

confidence: 99%

“…and N 2 slow down the dissipation of θ Q and θ C to 0 and reduce the aligning torque T ela exerted on the swimmer due to substrates aligning force F exter and the surface anchoring force F anc . As discussed in [31], the convergence rate of swimming direction α to the stable direction for an elongated swimmer is a competition between the torque T hydro due to hydrodynamic interactions and the torque T ela due to elastic interactions induced by F exter and F anc . This reducing of the aligning torque T ela makes the convergence of swimming direction α to the direction favored by the aligning force and surface anchoring less pronounced.…”

Section: Discussionmentioning

confidence: 99%

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Interaction of Microswimmers in Viscoelastic Liquid Crystals

Chi

Gavrikov

Berlyand

et al. 2022

Preprint

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Swimming bacteria successfully colonize complex non-Newtonian environments exemplified by viscoelastic media and even liquid crystals. While there is a significant body of research on microswimmer motility in viscoelastic liquids, the field still lacks clarity. This paper studies how individual microswimmers (e.g., bacteria) interact in a mucus-like environment modeled by a visco-elastic liquid crystal. We have found that an individual swimmer moves faster along the same track after the direction reversal, in faithful agreement with the experiment. This behavior is attributed to the formation of the transient tunnel due to the visco-elastic medium memory. We observed that the aft swimmer has a higher velocity for two swimmers along the same track and catches up with the leading swimmer. Multiple swimmers launched at different angles form a “train”: after some transient, the following swimmers repeat the path of the “leader”. Our results shed light on bacteria penetration in mucus and colonization of heterogeneous liquid environments.

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Section: Resultssupporting

confidence: 82%

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Interaction of Microswimmers in Viscoelastic Liquid Crystals

Chi

Gavrikov

Berlyand

et al. 2022

Preprint

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“…Recently, Lintuvuori et al [ 16 ] have studied the reorientation dynamics of a spherical squirmer in nematic LC and found that at steady state pushers (pullers) swim parallel (perpendicular) to the nematic director. The analytical calculation showed that the reorientation dynamics of a spherical squirmer is governed by a nematodynamic toque associate with the squirmer’s flow field and anisotropic viscosity of the suspending medium [ 16 – 18 ]. This unique behaviour of the microswimmers was utilized to transport cargo of cells/particles along prescribed pathways determined by the local nematic director field over long distances [ 14 , 19 , 20 ].…”

Section: Introductionmentioning

confidence: 99%

“…A closer look into the theoretical literature shows that dynamics of microswimmers in LCs have been investigated using either the lattice Boltzmann method [ 16 ] or finite element method [ 18 ]. These methods solve the nematodynamics but do not include thermal fluctuations.…”

Section: Introductionmentioning

confidence: 99%

Multiparticle collision dynamics simulations of a squirmer in a nematic fluid

Mandal

Mazza

2021

Eur. Phys. J. E

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We study the dynamics of a squirmer in a nematic liquid crystal using the multiparticle collision dynamics (MPCD) method. A recently developed nematic MPCD method [Phys. Rev. E 99, 063319 (2019)] which employs a tensor order parameter to describe the spatial and temporal variations of the nematic order is used to simulate the suspending anisotropic fluid. Considering both nematodynamic effects (anisotropic viscosity and elasticity) and thermal fluctuations, in the present study, we couple the nematic MPCD algorithm with a molecular dynamics (MD) scheme for the squirmer. A unique feature of the proposed method is that the nematic order, the fluid, and the squirmer are all represented in a particle-based framework. To test the applicability of this nematic MPCD-MD method, we simulate the dynamics of a spherical squirmer with homeotropic surface anchoring conditions in a bulk domain. The importance of anisotropic viscosity and elasticity on the squirmer’s speed and orientation is studied for different values of self-propulsion strength and squirmer type (pusher, puller or neutral). In sharp contrast to Newtonian fluids, the speed of the squirmer in a nematic fluid depends on the squirmer type. Interestingly, the speed of a strong pusher is smaller in the nematic fluid than for the Newtonian case. The orientational dynamics of the squirmer in the nematic fluid also shows a non-trivial dependence on the squirmer type. Our results compare well with existing experimental and numerical data. The full particle-based framework could be easily extended to model the dynamics of multiple squirmers in anisotropic fluids. Graphic abstract

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Liquid Crystalline Systems from Nature and Interaction of Living Organisms with Liquid Crystals

Kim

et al. 2022

Advanced Materials

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The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/adma.202204275. of biosensors with additional functionalities (e.g., self-regulated drug release) that are not available in previous systems is reviewed. Examples addressed in this review convey the message that the intersection between biomaterials and LCs offers deep insights into fundamental understanding of biomaterials, and provides resources for development of transformative technologies.

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Surface anchoring controls orientation of a microswimmer in nematic liquid crystal

Cited by 21 publications

References 39 publications

Interaction of Microswimmers in Viscoelastic Liquid Crystals

Interaction of Microswimmers in Viscoelastic Liquid Crystals

Multiparticle collision dynamics simulations of a squirmer in a nematic fluid

Liquid Crystalline Systems from Nature and Interaction of Living Organisms with Liquid Crystals

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