Star Polymers Viewed as Ultrasoft Colloidal Particles

Likos, Christos N.; Löwen, Hartmut; Watzlawek, M.; Abbas, Basil; Jucknischke, O.; Allgaier, Jürgen; Richter, D.

doi:10.1103/physrevlett.80.4450

Cited by 499 publications

(687 citation statements)

References 11 publications

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“…Star polymers have been explored in detail, since they exemplify stable, long hairy particles. At high concentrations, they deform but also interpenetrate via their grafted arms, as reflected by their effective interactions: their tunability at the molecular level allows repulsive pair potentials ranging from ultrasoft to hard as their functionality (number of arms) f S changes from typically below 30 to above 400 [8]. The very same deformability also determines their purely entropic interactions with planar or curved hard walls [9].…”

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confidence: 93%

Glassy States in Asymmetric Mixtures of Soft and Hard Colloids

et al. 2013

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By employing rheological experiments, mode coupling theory, and computer simulations based on realistic coarse-grained models, we investigate the effects of small, hard colloids on the glassy states formed by large, soft colloids. Multiarm star polymers mimic hard and soft colloids by appropriately varying the number and size of their arms. The addition of hard colloids leads, depending on their concentration, to either melting of the soft glass or the emergence of two distinct glassy states. We explain our findings by depletion of the colloids adjacent to the stars, which leads to an arrested phase separation when the repulsive glass line meets the demixing binodal. The parameter-free agreement between experiment, theory, and simulations suggests the generic nature of our results and opens the route for designing soft-hard colloidal composites with tunable rheology.

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confidence: 93%

Glassy States in Asymmetric Mixtures of Soft and Hard Colloids

et al. 2013

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“…Such soft potentials arise as the effective interaction potential between polymers or soft macromolecules in solution [25][26][27][28][29][30][31][32][33][34][35][36][37]. Our main reason for considering this model centres on the fact that the structure and phase behaviour (i.e.…”

Section: Model Fluidmentioning

confidence: 99%

Generation of Defects and Disorder from Deeply Quenching a Liquid to Form a Solid

Archer

Walters

Thiele

et al. 2016

Springer Proceedings in Mathematics &Amp; Statistics

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We show how deeply quenching a liquid to temperatures where it is linearly unstable and the crystal is the equilibrium phase often produces crystalline structures with defects and disorder. As the solid phase advances into the liquid phase, the modulations in the density distribution created behind the advancing solidification front do not necessarily have a wavelength that is the same as the equilibrium crystal lattice spacing. This is because in a deep enough quench the front propagation is governed by linear processes, but the crystal lattice spacing is determined by nonlinear terms. The wavelength mismatch can result in significant disorder behind the front that may or may not persist in the latter stage dynamics. We support these observations by presenting results from dynamical density functional theory calculations for simple one-and two-component two-dimensional systems of soft core particles.

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“…The factor 5/18 is found by matching the cone approximation for Θ (2) f f to the known values of the contact exponents for f = 1, 2 [1]. This matching in turn proposes an approximate value for the η f exponents, The prefactor Θ f 1 f 2 of the force between two star polymers at short distance calculated in non-resummed 1-loop and resummed 3-loop RG analysis in comparison to the result of the cone approximation.…”

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confidence: 99%

“…While such a behavior was already predicted by early scaling arguments [4] only recently corresponding experiments have become feasible with sufficiently dense stars. In addition theory and computer simulation have refined the original estimate for the number of chains f necessary for a freezing transition from f ∼ 100 to f ∼ 34 and predicted a rich phase diagram [1]. These results were derived using an effective pair potential between stars [1] with a short distance behavior derived from scaling theory as explained below.…”

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confidence: 99%