2019
DOI: 10.1088/1361-648x/ab0f6d
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Controlled self-aggregation of polymer-based nanoparticles employing shear flow and magnetic fields

Abstract: Star polymers with magnetically functionalized end groups are presented as a novel polymeric system whose morphology, self-aggregation, and orientation can easily be tuned by exposing these macromolecules simultaneously to an external magnetic field and to shear forces. Our investigations are based on a specialized simulation technique which faithfully takes into account the hydrodynamic interactions of the surrounding, Newtonian solvent. We find that the combination of magnetic field (including both strength … Show more

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Cited by 8 publications
(7 citation statements)
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“…Another evidence for this hypothesis is provided by the fact that in the stress vs. strain curves their maximum does not disappear at low shear rates where τ s τ h . The above mentioned features are in striking contrast to non-Newtonian fluids (such as supercooled liquids [12,15], ferrofluids [46], polymers [47], mixtures of ferrofluids and liquid crystals [48], to name a few) where only diffusion of the particles is responsible for the stress relaxation, and the maximum in the stress vs. strain response disappears at low shear rates, i.e. where τ s is comparable to structural relaxation times.…”
Section: Stress Vs Strain Responsementioning
confidence: 94%
“…Another evidence for this hypothesis is provided by the fact that in the stress vs. strain curves their maximum does not disappear at low shear rates where τ s τ h . The above mentioned features are in striking contrast to non-Newtonian fluids (such as supercooled liquids [12,15], ferrofluids [46], polymers [47], mixtures of ferrofluids and liquid crystals [48], to name a few) where only diffusion of the particles is responsible for the stress relaxation, and the maximum in the stress vs. strain response disappears at low shear rates, i.e. where τ s is comparable to structural relaxation times.…”
Section: Stress Vs Strain Responsementioning
confidence: 94%
“…It is known that soft condensed matter (or soft matter for short) can assemble into an array of nontrivial structures under non-equilibrium conditions. These can be considered dynamic phase transitions, which may be readily observed over time scales that can be realized in experiments. Indeed, a variety of soft matter systems have been studied over a number of years, including effective self-propelling particles, , polymer blends, , and colloids, among others. …”
mentioning
confidence: 99%
“…Furthermore, this analytical theory can serve as the starting point for predictions of viscosity and rheology of sheared colloidal suspensions, as well as in systems such as plasmas and dusty plasmas [28]. In the case of colloidal systems, this approach could be combined, in future work, with Mode-Coupling Theory [29,30,31,32,33] to arrive at predictions of dynamics and rheological response of interacting colloidal particles under strong shear flows; also, it could be used to predict and model controlled self-assembly of nanoparticles using shear flow [34].…”
Section: Conclusion and Future Stepsmentioning
confidence: 99%