Microswimmers – From Single Particle Motion to Collective Behavior

Gompper, Gerhard; Bechinger, Clemens; Herminghaus, Stephan; Isele-Holder, Rolf E.; Kaupp, U. Benjamin; Löwen, Hartmut; Stark, Holger; Winkler, Roland G.

doi:10.1140/epjst/e2016-60095-3

Cited by 25 publications

(24 citation statements)

References 20 publications

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“…These are nearly always very complex due to the interplay between gradients from individual particles and the perturbation from neighboring particles [4,5]. Different approaches of nonequilibrium statistical physics have been applied in studies on the self-assembly of active particles [3,66,67], however, only a few theories have explicitly taken the details of interactions into account [48,68]. We anticipate that mapping out the involved local gradients, their evolutions and fluctuations in sufficient detail will yield valuable complementary information to standard particle tracking approaches.…”

Section: Discussionmentioning

confidence: 99%

Large scale micro-photometry for high resolution pH-characterization during electro-osmotic pumping and modular micro-swimming

et al. 2017

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Micro-fluidic pumps as well as artificial micro-swimmers are conveniently realized exploiting phoretic solvent flows based on local gradients of temperature, electrolyte concentration or pH. We here present a facile micro-photometric method for monitoring pH gradients and demonstrate its performance and scope on different experimental situations including an electro-osmotic pump and modular micro-swimmers assembled from ion exchange resin beads and polystyrene colloids. In combination with the present microscope and DSLR camera our method offers a 2 μm spatial resolution at video frame rate over a field of view of 3920×2602 μm 2 . Under optimal conditions we achieve a pH-resolution of 0.05 with about equal contributions from statistical and systematical uncertainties. Our quantitative micro-photometric characterization of pH gradients which develop in time and reach out several mm is anticipated to provide valuable input for reliable modeling and simulations of a large variety of complex flow situations involving pH-gradients including artificial micro-swimmers, microfluidic pumping or even electro-convection.

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Section: Discussionmentioning

confidence: 99%

Large scale micro-photometry for high resolution pH-characterization during electro-osmotic pumping and modular micro-swimming

et al. 2017

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“…A more complicated coupling involves a concentration dependent prefactor α as proposed in Ref. 14 We will basically use and discuss formula (18) in the sequel. The effective chemotactic force typically acts on a completely overdamped particle with position r p (t), leading to the following equation of motion:…”

Section: Chemotactic Coupling and Secreting Particle Dynamicsmentioning

confidence: 99%

Modeling Chemotaxis of Microswimmers: From Individual to Collective Behavior

Liebchen¹,

Löwen²

2019

Chemical Kinetics

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We discuss recent progress in the theoretical description of chemotaxis by coupling the diffusion equation of a chemical species to equations describing the motion of sensing microorganisms. In particular, we discuss models for autochemotaxis of a single microorganism which senses its own secretion leading to phenomena such as self-localization and selfavoidance. For two heterogeneous particles, chemotactic coupling can lead to predator-prey behavior including chase and escape phenomena, and to the formation of active molecules, where motility spontaneously emerges when the particles approach each other. We close this review with some remarks on the collective behavior of many particles where chemotactic coupling induces patterns involving clusters, spirals or traveling waves. 1 arXiv:1802.07933v2 [cond-mat.soft]

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“…They are still a very active field of research, posing a wide variety of problems. Interesting topics of recent research are systems with slow relaxation (e. g. aging in molecular glasses), strongly driven systems (e. g. granular matter or strongly perturbed colloidal systems), and active matter (comprising, e. g., living organisms and artificial microswimmers) …”

Section: Non‐equilibrium Brownian Thermometrymentioning

confidence: 99%

“…Interesting topics of recent research are systems with slow relaxation (e. g. aging in molecular glasses), strongly driven systems (e. g. granular matter or strongly perturbed colloidal systems), and active matter (comprising, e. g., living organisms and artificial microswimmers). [7,43,9,59] A key feature of equilibrium statistical mechanics is that it provides a means to accurately describe macroscopic systems in terms of a small number of thermodynamic variables (e. g. temperature, pressure). Far from equilibrium an analogous general framework is not available, and the very existence of key concepts of thermodynamics such as pressure or temperature is a priori questionable.…”

Section: Temperature Beyond Equilibriummentioning

confidence: 99%

“…A recent collection of minireviews on the topics of biological and artificial swimmers as well as collective motion can be found in. [43] To refer to the common traits of such living and biomimetic systems, the notion of "active matter" has been coined for this important class of non-equilibrium many-body systems that are not driven by some external forces but by "intrinsic" energyconsuming mechanisms. The active mechanisms break detailed balance on a microsopic or mesoscopic scale.…”

Section: Towards Complexity: Active and Biological Mattermentioning

confidence: 99%

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Brownian Thermometry Beyond Equilibrium

Geiß

Kroy

2019

ChemSystemsChem

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Since Albert Einstein's seminal 1905‐paper on Brownian motion, the temperature of fluids and gases of known viscosity can be deduced from observations of the fluctuations of small suspended probe particles. We summarize recent generalizations of this standard technique of Brownian thermometry to situations involving spatially heterogeneous temperature fields and other non‐equilibrium conditions in the solvent medium. The notion of effective temperatures is reviewed and its scope critically assessed. Our emphasis is on practically relevant real‐world applications, for which effective temperatures have been explicitly computed and experimentally confirmed. We also elucidate the relation to the more general concept of (effective) temperature spectra and their measurement by Brownian thermospectrometry. Finally, we highlight the conceptual importance of non‐equilibrium thermometry for active and biological matter, such as microswimmer suspensions or biological cells, which often play the role of non‐thermal (“active”) heat baths for embedded Brownian degrees of freedom.

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Microswimmers – From Single Particle Motion to Collective Behavior

Cited by 25 publications

References 20 publications

Large scale micro-photometry for high resolution pH-characterization during electro-osmotic pumping and modular micro-swimming

Large scale micro-photometry for high resolution pH-characterization during electro-osmotic pumping and modular micro-swimming

Modeling Chemotaxis of Microswimmers: From Individual to Collective Behavior

Brownian Thermometry Beyond Equilibrium

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