Diffusing wave paradox of phototactic particles in traveling light pulses

Lozano, Celia; Bechinger, Clemens

doi:10.1038/s41467-019-10535-z

Cited by 34 publications

(37 citation statements)

References 54 publications

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“…Further, Ag/poly(methyl methacrylate) Janus micromotors were able to self‐propel under pulsating and continuous visible light, achieving instantaneous (peak) velocities of 20–25 µm s −1 . Travelling light pulses also promoted the movement of phototactic particles, which were demonstrated to be able to track local light gradients . Further, inorganic Zn x Cd 1– x Se‐Cu 2 Se‐Pt p–n junction nanowire were explored as visible‐light‐driven micromotors with velocities up to 10 µm s −1 …”

Section: Externally Driven Nano‐ and Micromotorsmentioning

confidence: 99%

Recent Advances in Nano‐ and Micromotors

Fernández-Medina

Ramos-Docampo

Hovorka

et al. 2020

Adv Funct Materials

163

143

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Nano‐ and micromotors are fascinating objects that can navigate in complex fluidic environments. Their active motion can be triggered by external power sources or they can exhibit self‐propulsion using fuel extracted from their surroundings. The research field is rapidly evolving and has produced nano/micromotors of different geometrical designs, exploiting a variety of mechanisms of locomotion, being capable of achieving remarkable speeds in diverse environments ranging from simple aqueous solutions to complex media including cell cultures or animal tissue. This review aims to provide an overview of the recent developments with focus on predominantly experimental demonstrations of the various motor designs developed in the past 24 months. First, externally driven motors are discussed followed by considering fuel‐driven approaches. Finally, a short future perspective is provided.

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Section: Externally Driven Nano‐ and Micromotorsmentioning

confidence: 99%

Recent Advances in Nano‐ and Micromotors

Fernández-Medina

Ramos-Docampo

Hovorka

et al. 2020

Adv Funct Materials

163

143

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“…An important class of particles for which effective and versatile trapping schemes are currently not available are self-propelled active particles (APs) [9][10][11][12][13][14][15] . Such systems receive considerable attention due to their resemblance with motile microorganisms [16][17][18] , allowing to identify general conditions under which collective behavior can emerge 19,20 . In addition, APs are currently discussed as autonomous microrobots that may find use as autonomous vehicles to deliver loads to specific targets [21][22][23] .…”

mentioning

confidence: 99%

Realization of a motility-trap for active particles

et al. 2020

Self Cite

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Trapping of atomic and mesoscopic particles with optical fields is a practical technique employed in many research disciplines. Developing similar trapping methods for self-propelled, i.e. active, particles is, however, challenging due to the typical anisotropic material composition of Janus-type active particles. This renders their trapping with magneto-optical fields to be difficult. Here we present the realization of a motility-trap for active particles, which only exploits their self-propulsion properties. By combining experiments, numerical simulations, and theory, we show that, under appropriate conditions, a force-free rotation of the self-propulsion direction towards the trap's center can be achieved, which results in an exponential localization of active particles. Because this trapping mechanism can be applied to any propulsion scheme, we expect such motility-tweezers to be relevant for fundamental studies of self-driven objects as well as for their applications as autonomous microrobots.

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“…The width of a lane can be approximated as d = L/(2π) ∼ 0.1 cm. Note that for the chosen parameters the diffusive Hall-constant is of the order, κ = qB/γ ∼ 0.1 (29) implying that Lorentz force becomes comparable to frictional force on the particle. Finally, assuming that the diffusion coefficient of the tracer particle is D p ∼ 10 −13 m 2 /s, a reasonable estimate for large tracer particles (∼ µm), we obtain from Eq.…”

Section: Passive Diffusion Of Tracer Particlementioning

confidence: 99%

“…[23]. Whereas in these studies activity has been time independent, one can induce fluxes by making the swim speed space and time dependent, as has been shown in theoretical and numerical studies [24][25][26][27][28][29]. In these systems the active particles 'surf' on an activity wave resulting in active fluxes.…”

Section: Introductionmentioning

confidence: 99%

Lorentz forces induce inhomogeneity and flux in active systems

Vuijk

Sommer

Merlitz

et al. 2020

Phys. Rev. Research

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We consider the nonequilibrium dynamics of a charged active Brownian particle in the presence of a space dependent magnetic field. It has recently been shown that the Lorentz force induces a particle flux perpendicular to density gradients, thus preventing a diffusive description of the dynamics. Whereas a passive system will eventually relax to an equilibrium state, unaffected by the magnetic field, an active system subject to a spatially varying Lorentz force settles into a nonequilibrium steady state characterized by an inhomogeneous density and divergence-free bulk fluxes. A macroscopic flux of charged active particles is induced by the gradient of the magnetic field only and does not require additional symmetric breaking such as density or potential gradients. This stands in marked contrast to similar phenomena in condensed matter such as the classical Hall effect. In a confined geometry we observe circulating fluxes, which can be reversed by inverting the direction of the magnetic field. Our theoretical approach, based on coarse-graining of the Fokker-Planck equation, yields analytical results for the density, fluxes, and polarization in the steady state, all of which are validated by direct computer simulation. We demonstrate that passive tracer particles can be used to measure the essential effects of the Lorentz force on the active particle bath, and we discuss under which conditions the effects of the flux could be observed experimentally.arXiv:1908.02577v1 [cond-mat.soft]

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Diffusing wave paradox of phototactic particles in traveling light pulses

Cited by 34 publications

References 54 publications

Recent Advances in Nano‐ and Micromotors

Recent Advances in Nano‐ and Micromotors

Realization of a motility-trap for active particles

Lorentz forces induce inhomogeneity and flux in active systems

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