Hydrodynamic inflation of ring polymers under shear

Liebetreu, Maximilian; Likos, Christos N.

doi:10.1038/s43246-019-0006-5

Cited by 31 publications

(45 citation statements)

References 99 publications

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“…occur in rings, this should happen at higher rates which are not accessible experimentally at the moment. The conjecture of different conformation in sheared ring and linear polymers is supported by recent insightful evidence about their response in dilute or non-dilute solution from both experiments [10,50] and simulations [51][52][53], as well as simulations and modeling in the melt state [11,[13][14][15][16]. to 160 °C by using the shift factors reported in Ref.…”

Section: Resultsmentioning

confidence: 70%

Nonlinear rheometry of entangled polymeric rings and ring-linear blends

Parisi

Kaliva

Costanzo

et al. 2021

Journal of Rheology

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We present a comprehensive experimental rheological dataset for purified entangled ring polystyrenes and their blends with linear chains in nonlinear shear and elongation. In particular, data for shear stress growth coefficient, steady-state shear viscosity, and first and second normal stress differences are obtained and discussed as functions of shear rate as well as molecular parameters (molar mass, blend composition and decreasing molar mass of linear component in blend). Over the extended parameter range investigated, rings do not exhibit clear transient undershoot in shear, in contrast to their linear counterparts and ring-linear blends. For the latter, the size of the undershoot and respective strain appear to increase with shear rate. Universal scaling of strain at overshoot and fractional overshoot (ratio of maximum to steady-state shear stress growth coefficient) indicates subtle differences in the shear-rate dependence between rings and linear polymers or their blends.

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Section: Resultsmentioning

confidence: 70%

Nonlinear rheometry of entangled polymeric rings and ring-linear blends

Parisi

Kaliva

Costanzo

et al. 2021

Journal of Rheology

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“…Such responsive building blocks that can self-organize into higher-order structures may form soft patchy particles, which have directional interactions and varying softness. Furthermore, topological effects that arise in systems with complex architecture can alone lead to a range of interesting phenomena in and out of thermodynamic equilibrium for both low [9][10][11][12][13][14][15] and high system densities [16][17][18][19][20][21]. Functionalized biomolecules such as DNA-grafted colloidal particles represent a typical example where patchiness reflects the competition between inter-and intra-particle associations [22][23][24][25].…”

Section: Introductionmentioning

confidence: 99%

The influence of arm composition on the self-assembly of low-functionality telechelic star polymers in dilute solutions

et al. 2020

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We combine synthesis, physical experiments, and computer simulations to investigate self-assembly patterns of low-functionality telechelic star polymers (TSPs) in dilute solutions. In particular, in this work, we focus on the effect of the arm composition and length on the static and dynamic properties of TSPs, whose terminal blocks are subject to worsening solvent quality upon reducing the temperature. We find two populations, single stars and clusters, that emerge upon worsening the solvent quality of the outer block. For both types of populations, their spatial extent decreases with temperature, with the specific details (such as temperature at which the minimal size is reached) depending on the coupling between inter- and intra-molecular associations as well as their strength. The experimental results are in very good qualitative agreement with coarse-grained simulations, which offer insights into the mechanism of thermoresponsive behavior of this class of materials.

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“…Neglecting hydrodynamics has allowed us to robustly investigate rings of large size for long time scales. Nevertheless, hydrodynamic interactions will be crucial to investigate the dynamics and the stability of the open conformations at small values of N [54]. Granted the phenomenology observed in this paper is robust, active rings may be exploited to wrap, protect and deliver drugs.…”

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confidence: 84%

Active polymer rings: activity-induced collapse and dynamical arrest

Locatelli,

Bianco,

Malgaretti

2021

Preprint

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We investigate, using numerical simulations, the conformations of isolated active ring polymers. We find that the their behaviour depends crucially on their size: short rings (N 100) are swelled whereas longer rings (N 200) collapse, at sufficiently high activity. By investigating the nonequilibrium process leading to the steady state, we find a universal route driving both outcomes; we highlight the central role of steric interactions, at variance with linear chains, and of topology conservation. We further show that the collapsed rings are arrested by looking at different observables, all underlining the presence of an extremely long time scales at the steady state, associated with the internal dynamics of the collapsed section. Finally, we found that is some circumstances the collapsed state spins about its axis.

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Hydrodynamic inflation of ring polymers under shear

Cited by 31 publications

References 99 publications

Nonlinear rheometry of entangled polymeric rings and ring-linear blends

Nonlinear rheometry of entangled polymeric rings and ring-linear blends

The influence of arm composition on the self-assembly of low-functionality telechelic star polymers in dilute solutions

Active polymer rings: activity-induced collapse and dynamical arrest

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