Anomalous dynamics of intruders in a crowded environment of mobile obstacles

Sentjabrskaja, Tatjana; Zaccarelli, Emanuela; Michele, Cristiano De; Sciortino, Francesco; Tartaglia, P.; Voigtmann, Thomas; Egelhaaf, Stefan U.; Laurati, Marco

doi:10.1038/ncomms11133

Cited by 125 publications

(151 citation statements)

References 48 publications

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“…As compared to micelles formed in 95% water, a six order of magnitude decrease in the diffusion coefficient of the micelles is observed when the micelles are present in 20% water, the rest being glucose, urea and surfactant. The evolution of the micelles' correlation function with a decrease in water concentration is analogous to that observed in colloids under jammed state 25,26 . In particular, the correlation function changes from a single exponential to a double exponential function as is observed in the case of arrested macromolecules in a crowded environment 27 .…”

Section: Resultssupporting

confidence: 60%

Dynamically arrested micelles in a supercooled sugar urea melt

et al. 2018

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Micelles are nanoscopic, dynamic, equilibrium structures formed by the association of amphiphiles in a liquid. To date, freezing of disordered micelles typically requires cryogenic quenching. This avoids crystallization of the solvent or surfactant, mitigating against micelle destruction. Here we describe a method to create disordered, dynamically arrested waterfree micelles, trapped in a glass-forming solvent at ambient temperature. The micelles are formed by dissolving a surfactant in a molten mixture of sugar (fructose or glucose) and urea. These micelles are trapped in a supercooled state upon cooling the mixture, forming an amorphous micro-heterogeneous material driven by hydrogen bonding interactions. Since all components used in this formulation are solid at room temperature, the supercooled micelle formation is analogous to biphasic alloy formation in metals. This method may provide a way to prepare microphase separated organic solids and to control diffusion-limited aggregation of nanoparticles.

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Section: Resultssupporting

confidence: 60%

Dynamically arrested micelles in a supercooled sugar urea melt

et al. 2018

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“…These data are treated via an image processing algorithm [22] or equivalent versions of it [23] that combines image differences and spatial Fourier transformations to obtain as a result the intermediate scattering function f (q,t) that is typically probed in DLS experiments as a function of the scattering wave vector q and time t [24]. Since its introduction, DDM has been profitably used and also extended by several groups [25][26][27][28][29][30][31][32][33][34] for a variety of applications [35]. In particular, DDM has been recently proven to be an effective tool to measure also the rotational dynamics of anisotropic colloidal particles in solution.…”

Section: Introductionmentioning

confidence: 99%

Differential dynamic microscopy microrheology of soft materials: A tracking-free determination of the frequency-dependent loss and storage moduli

Edera

Bergamini

Trappe

et al. 2017

Phys. Rev. Materials

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Particle-tracking microrheology (PT-μr) exploits the thermal motion of embedded particles to probe the local mechanical properties of soft materials. Despite its appealing conceptual simplicity, PT-μr requires calibration procedures and operating assumptions that constitute a practical barrier to its wider application. Here we demonstrate differential dynamic microscopy microrheology (DDM-μr), a tracking-free approach based on the multiscale, temporal correlation study of the image intensity fluctuations that are observed in microscopy experiments as a consequence of the translational and rotational motion of the tracers. We show that the mechanical moduli of an arbitrary sample are determined correctly over a wide frequency range provided that the standard DDM analysis is reinforced with an iterative, self-consistent procedure that fully exploits the multiscale information made available by DDM. Our approach to DDM-μr does not require any prior calibration, is in agreement with both traditional rheology and diffusing wave spectroscopy microrheology, and works in conditions where PT-μr fails, providing thus an operationally simple, calibration-free probe of soft materials.

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“…Recently, it has been shown that the ISF can also be obtained from advanced image correlation spectroscopy such as dynamic differential microscopy (DDM) [36,68,69], a method that is also suited to resolve the motion of active particles [70,71]. Here we focus again on tracer particles that are located on the infinite cluster only and modify the definition of the ISF accordingly to…”

Section: Space-resolved Transportmentioning

confidence: 99%

“…For example, for the alkali silica melts [26][27][28][29] the preferential diffusion pathways for the alkali ions emerge as a quasi-arrested defect structure of a tetrahedral network. Similarly, for size-disparate soft [31] or hard spheres [36] the interaction between the particles leads to strong short-range correlations which modify locally the structure of the pores. Nevertheless fingerprints of the anomalous dynamics as predicted for the Lorentz models are clearly found in all these systems.…”

Section: Quenched Host Structuresmentioning

confidence: 99%

“…Within MCT this is connected to a delocalization transition for the small particles [35] which diffuse through an arrested matrix of big particles. An experimental realization of such a strongly size-disparate mixture has been achieved for colloids only recently by Sentjabrskaja et al [36]. There the experimental challenge was to resolve the dynamics of the small particles which rearrange too fast for conventional particle tracking.…”

Section: Introductionmentioning

confidence: 99%

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Complex dynamics induced by strong confinement – From tracer diffusion in strongly heterogeneous media to glassy relaxation of dense fluids in narrow slits

Mandal

Spanner-Denzer

Leitmann

et al. 2017

Eur. Phys. J. Spec. Top.

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Abstract. We provide an overview of recent advances of the complex dynamics of particles in strong confinements. The first paradigm is the Lorentz model where tracers explore a quenched disordered host structure. Such systems naturally occur as limiting cases of binary glassforming systems if the dynamics of one component is much faster than the other. For a certain critical density of the host structure the tracers undergo a localization transition which constitutes a critical phenomenon. A series of predictions in the vicinity of the transition have been elaborated and tested versus computer simulations. Analytical progress is achieved for small obstacle densities. The second paradigm is a dense strongly interacting liquid confined to a narrow slab. Then the glass transition depends nonmonotonically on the separation of the plates due to an interplay of local packing and layering. Very small slab widths allow to address certain features of the statics and dynamics analytically.

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Anomalous dynamics of intruders in a crowded environment of mobile obstacles

Cited by 125 publications

References 48 publications

Dynamically arrested micelles in a supercooled sugar urea melt

Dynamically arrested micelles in a supercooled sugar urea melt

Differential dynamic microscopy microrheology of soft materials: A tracking-free determination of the frequency-dependent loss and storage moduli

Complex dynamics induced by strong confinement – From tracer diffusion in strongly heterogeneous media to glassy relaxation of dense fluids in narrow slits

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