Hydrodynamic correlations and diffusion coefficient of star polymers in solution

Singh, Sunil P.; Huang, Chien-Cheng; Westphal, Elmar; Gompper, Gerhard; Winkler, Roland G.

doi:10.1063/1.4893766

Cited by 32 publications

(23 citation statements)

References 85 publications

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“…The inclusion of hydrodynamic interactions revealed an additional reduction of D r of proteins [102]. The reader is also referred to the simulation study [103] in which the self-diffusion of star-like polymers in the presence of hydrodynamic interactions [104] was examined in detail. The paper is organised as follows.…”

Section: Introductionmentioning

confidence: 99%

Self-subdiffusion in solutions of star-shaped crowders: non-monotonic effects of inter-particle interactions

2015

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We examine by extensive computer simulations the self-diffusion of anisotropic star-like particles in crowded two-dimensional solutions. We investigate the implications of the area coverage fraction f of the crowders and the crowder-crowder adhesion properties on the regime of transient anomalous diffusion. We systematically compute the mean squared displacement (MSD) of the particles, their time averaged MSD, and the effective diffusion coefficient. The diffusion is ergodic in the limit of long traces, such that the mean time averaged MSD converges towards the ensemble averaged MSD, and features a small residual amplitude spread of the time averaged MSD from individual trajectories. At intermediate time scales, we quantify the anomalous diffusion in the system. Also, we show that the translational-but not rotational-diffusivity of the particles D is a nonmonotonic function of the attraction strength between them. Both diffusion coefficients decrease as the power law D 1with the area fraction f occupied by the crowders and the critical value . f Our results might be applicable to rationalising the experimental observations of non-Brownian diffusion for a number of standard macromolecular crowders used in vitro to mimic the cytoplasmic conditions of living cells.

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Section: Introductionmentioning

confidence: 99%

Self-subdiffusion in solutions of star-shaped crowders: non-monotonic effects of inter-particle interactions

2015

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“…Most reported simulation data, even since the publication of these results, neglect this contribution and therefore underestimate the diffusion coefficient. Nevertheless, this scaling law has been verified numerically for a number of systems, including several popular water models [5][6][7], ionic liquids [8] or more complex fluids such as solutions of star polymers [9] and even in higher dimensional spaces [10]. This scaling then allows extrapolating the solvent diffusion coefficient to the macroscopic L → ∞ limit, or computing the correction to be applied for solutes [11,12].…”

Section: Introductionmentioning

confidence: 91%

Diffusion in bulk liquids: finite-size effects in anisotropic systems

2015

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We investigate systematically the effect of the cell size and shape on the diffusion properties in molecular dynamics simulations. Specifically, we consider a bulk Lennard-Jones fluid in orthorhombic cells with one length differing from the other two. The components of the diffusion tensor display complex variations as a function of the two independent lengths and may even become in some cases larger than the macroscopic limit for a cubic cell. These results can be perfectly explained by a purely hydrodynamic theory, which extends results obtained previously for the isotropic case. We provide the explicit expression of the diffusion tensor, including the effect of the finite size of the diffusing particle. The simulation results follow a simple scaling as a function of box size and aspect ratio and the corresponding scaling functions are determined numerically. These findings should have implications for the practically more relevant case of confined fluids.

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“…A few works have been devoted to electrophoresis of polyelectrolytes and their counterions [25,26]. Some of us have recently demonstrated the possibility of studying the influence of concentration on the transport properties of electrolytes coupling SRD with charged solutes [27].…”

Section: Introductionmentioning

confidence: 99%

Stochastic rotation dynamics simulation of electro-osmosis

et al. 2015

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Stochastic Rotation Dynamics (SRD) is a mesoscale simulation technique that captures hydrodynamic couplings in simple and complex fluids. It can be used in various hydrodynamic regimes and it is not restricted to specific geometries. We show here that SRD using the collisional coupling approach to capture momentum transfer between the semi-implicit solvent and the explicit counterions, is able to describe electro-kinetic effects, i.e. coupled electrostatic and hydrodynamic phenomena occurring at charged solid-liquid interfaces. The method is first validated for electro-osmosis in the simple case of a slit pore without added salt, for which an analytical solution of the Helmholtz-Smoluchowski theory is known, in a physical regime where this mean-field theory is valid. We then discuss the predictions of SRD for electro-osmosis beyond the range of validity of the Helmholtz-Smoluchowski (or Poisson-Nernst-Planck) theory, in particular due to ion-ion correlations at the surface, to charge localisation on discrete sites at the solid surface and to surface charge heterogeneity, that all contribute to a reduction of the electro-osmotic flow. In order to disentangle these last two aspects, we also investigate at the mean-field level a simple system with alternate charged and neutral stripes, using lattice-Boltzmann electro-kinetics simulations. Overall, this work opens new perspectives for the use of SRD as a generic mesoscopic simulation method for soft matter problems, in particular under confinement, since in practice many interfaces between fluids and solids are charged.

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Hydrodynamic correlations and diffusion coefficient of star polymers in solution

Cited by 32 publications

References 85 publications

Self-subdiffusion in solutions of star-shaped crowders: non-monotonic effects of inter-particle interactions

Self-subdiffusion in solutions of star-shaped crowders: non-monotonic effects of inter-particle interactions

Diffusion in bulk liquids: finite-size effects in anisotropic systems

Stochastic rotation dynamics simulation of electro-osmosis

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