Boosting migration of large particles by solute contrasts

Abécassis, Benjamin; Cottin-Bizonne, Cécile; Ybert, Christophe; Ajdari, Armand; Bocquet, Lydéric

doi:10.1038/nmat2254

Cited by 264 publications

(347 citation statements)

References 27 publications

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“…It results from an unbalanced osmotic pressure occurring within the diffuse layer in the close vicinity of a solid surface (typically of the order of a few nanometres), which thereby plays the role of the semipermeable membrane in the classical osmosis. This induces an interfacial flow along the surface, leading to the motion of the particle in the surrounding medium [27,28]. Diffusiophoresis is therefore material-and pH-dependent, because it originates from the interaction between the solute and the solid surface.…”

Section: Photo-activated Colloids (A) Photocatalytic Materialsmentioning

confidence: 99%

Light-activated self-propelled colloids

Palacci

Sacanna

Kim

et al. 2014

Phil. Trans. R. Soc. A.

130

133

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Light-activated self-propelled colloids are synthesized and their active motion is studied using optical microscopy. We propose a versatile route using different photoactive materials, and demonstrate a multiwavelength activation and propulsion. Thanks to the photoelectrochemical properties of two semiconductor materials (α-Fe 2 O 3 and TiO 2 ), a light with an energy higher than the bandgap triggers the reaction of decomposition of hydrogen peroxide and produces a chemical cloud around the particle. It induces a phoretic attraction with neighbouring colloids as well as an osmotic selfpropulsion of the particle on the substrate. We use these mechanisms to form colloidal cargos as well as self-propelled particles where the light-activated component is embedded into a dielectric sphere. The particles are self-propelled along a direction otherwise randomized by thermal fluctuations, and exhibit a persistent random walk. For sufficient surface density, the particles spontaneously form 'living crystals' which are mobile, break apart and reform. Steering the particle with an external magnetic field, we show that the formation of the dense phase results from the collisions heads-on of the particles. This effect is intrinsically non-equilibrium and a novel principle of organization for systems without detailed balance. Engineering families of particles self-propelled by different wavelength demonstrate a good understanding of both the physics and the chemistry behind the system and points to a general route for designing new families of self-propelled particles.

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Section: Photo-activated Colloids (A) Photocatalytic Materialsmentioning

confidence: 99%

Light-activated self-propelled colloids

Palacci

Sacanna

Kim

et al. 2014

Phil. Trans. R. Soc. A.

130

133

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“…Generally, there are two classes of swimmers: systems driven by and aligning with external fields (11)(12)(13)(14), including chemotactic gradients, and selfpropelled swimmers, which move autonomously in homogeneous environments (15)(16)(17)(18)(19)(20)(21). Many autonomous swimmers additionally react to external fields, e.g., phototactic gradients (22).…”

mentioning

confidence: 99%

Chemotaxis and autochemotaxis of self-propelling droplet swimmers

Jin

Krüger

Maaß

2017

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

256

257

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Chemotaxis and autochemotaxis play an important role in many essential biological processes. We present a self-propelling artificial swimmer system that exhibits chemotaxis as well as negative autochemotaxis. Oil droplets in an aqueous surfactant solution are driven by interfacial Marangoni flows induced by micellar solubilization of the oil phase. We demonstrate that chemotaxis along micellar surfactant gradients can guide these swimmers through a microfluidic maze. Similarly, a depletion of empty micelles in the wake of a droplet swimmer causes negative autochemotaxis and thereby trail avoidance. We studied autochemotaxis quantitatively in a microfluidic device of bifurcating channels: Branch choices of consecutive swimmers are anticorrelated, an effect decaying over time due to trail dispersion. We modeled this process by a simple one-dimensional diffusion process and stochastic Langevin dynamics. Our results are consistent with a linear surfactant gradient force and diffusion constants appropriate for micellar diffusion and provide a measure of autochemotactic feedback strength vs. stochastic forces. This assay is readily adaptable for quantitative studies of both artificial and biological autochemotactic systems.artificial swimmers | chemotaxis | autochemotaxis | microfluidics L ocomotion of living bacteria or cells can be random or oriented. Oriented motion comprises the various "taxis" strategies by which bacteria or cells react to changes in their environment (1). Among these, chemotaxis is one of the best-studied examples (2, 3): Cells and microorganisms are able to sense certain chemicals (chemoattractants or chemorepellents) and move toward or away from them. This is an essential function in many biological processes, e.g., wound healing, fertilization, pathogenic species invading a host, or colonization dynamics (4, 5). When the chemoattractant or chemorepellent is produced by the microorganisms themselves, the system exhibits positive or negative autochemotaxis. Thus, chemotaxis provides a mechanism of interindividual communication. Modeling such communication strategies is key to understanding the collective behavior of microorganisms (6-8) as well as flocks of animals like fire ants (9, 10).To model the swimming motion of microorganisms, various self-propelling artificial swimmer systems have been developed based on different mechanisms. Generally, there are two classes of swimmers: systems driven by and aligning with external fields (11-14), including chemotactic gradients, and selfpropelled swimmers, which move autonomously in homogeneous environments (15-21). Many autonomous swimmers additionally react to external fields, e.g., phototactic gradients (22).Biological autochemotactic systems exhibit very complex behaviors (23,24), where physical effects are intermingling with effects from various bioprocesses such as cell migration, metabolism, and division. To untangle these effects, there have been some design proposals for artificial systems, such as in ref.25, and simulations on the dynamics o...

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“…This peculiar 'log-sensing' property was also verified by recent experiments on diffusiophoresis in controlled electrolyte gradients. 1,2 We assume in our simulations that D dp is a constant independent of the silver concentration, and the weak dependence of D dp on salt concentration was indeed shown by Palacci et al 1 to play only a minimal role. The simpler scaling for D dp ∼ k B T/μl B has also been suggested, 32 where l B is the Bjerrum length (l B = 0.7 nm in water).…”

Section: Particle Fluxesmentioning

confidence: 57%

“…Recent advances in microfluidic technologies have spurred a renewed interest in the theoretical understanding and practical application of such transport mechanisms. 1,2 In recent years, phoretic effects have also been used for the autonomous self-propulsion of microparticles. Catalytically active microparticles such as bimetallic microrods can indeed self-generate and sustain surface asymmetries leading to their propulsion through a variety of self-phoretic mechanisms.…”

Section: Introductionmentioning

confidence: 99%

Motion-based threat detection using microrods: experiments and numerical simulations

et al. 2015

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Motion-based chemical sensing using microscale particles has attracted considerable recent attention. In this paper, we report on new experiments and Brownian dynamics simulations that cast light on the dynamics of both passive and active microrods (gold wires and gold-platinum micromotors) in a silver ion gradient. We demonstrate that such microrods can be used for threat detection in the form of a silver ion source, allowing for the determination of both the location of the source and concentration of silver.This threat detection strategy relies on the diffusiophoretic motion of both passive and active microrods in the ionic gradient and on the speed acceleration of the Au-Pt micromotors in the presence of silver ions. A Langevin model describing the microrod dynamics and accounting for all of these effects is presented, and key model parameters are extracted from the experimental data, thereby providing a reliable estimate for the full spatiotemporal distribution of the silver ions in the vicinity of the source.

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Boosting migration of large particles by solute contrasts

Cited by 264 publications

References 27 publications

Light-activated self-propelled colloids

Light-activated self-propelled colloids

Chemotaxis and autochemotaxis of self-propelling droplet swimmers

Motion-based threat detection using microrods: experiments and numerical simulations

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