Condensed Matter Theory

Exact results for strongly-correlated fermions in 2+1 dimensions

(2005)

Authors:

Paul Fendley, Kareljan Schoutens

Modeling a tethered polymer in Poiseuille flow

Journal of Chemical Physics 122:16 (2005)

Authors:

MA Webster, JM Yeomans

Abstract:

We investigate the behavior of a tethered polymer in Poiseuille flow using a multiscale algorithm. The polymer, treated using molecular dynamics, is coupled to a solvent modeled by the stochastic rotation algorithm, a particle-based Navier-Stokes integrator. The expected series of morphological transitions of the polymer: sphere to distorted sphere to trumpet to stem and flower to rod are recovered, and we discuss how the polymer extension depends on the flow velocity. Backflow effects cause an effective increase in viscosity, which appears to be primarily due to the fluctuations of the free end of the polymer. © 2005 American Institute of Physics.

Modeling a tethered polymer in Poiseuille flow.

J Chem Phys 122:16 (2005) 164903

Authors:

MA Webster, JM Yeomans

Abstract:

We investigate the behavior of a tethered polymer in Poiseuille flow using a multiscale algorithm. The polymer, treated using molecular dynamics, is coupled to a solvent modeled by the stochastic rotation algorithm, a particle-based Navier-Stokes integrator. The expected series of morphological transitions of the polymer: sphere to distorted sphere to trumpet to stem and flower to rod are recovered, and we discuss how the polymer extension depends on the flow velocity. Backflow effects cause an effective increase in viscosity, which appears to be primarily due to the fluctuations of the free end of the polymer.

Kinetic theory derivation of the transport coefficients of stochastic rotation dynamics.

J Phys Chem B 109:14 (2005) 6505-6513

Authors:

CM Pooley, JM Yeomans

Abstract:

We use a kinetic theory approach to derive the continuum Navier-Stokes and heat conduction equations for stochastic rotation dynamics, a particle based algorithm for simulating a fluid. Hence we obtain expressions for the viscosity and thermal conductivity in two and three dimensions. The predictions are tested numerically and good agreement is found.

Propulsion at low Reynolds number

Journal of Physics Condensed Matter 17:14 (2005)

Authors:

A Najafi, R Golestanian

Abstract:

We study the propulsion of two model swimmers at low Reynolds number. Inspired by Purcell's model, we propose a very simple one-dimensional swimmer consisting of three spheres that are connected by two arms whose lengths can change between two values. The proposed swimmer can swim with a special type of motion, which breaks the time-reversal symmetry. We also show that an ellipsoidal membrane with tangential travelling wave on it can also propel itself in the direction preferred by the travelling wave. This system resembles the realistic biological animals like Paramecium. © 2005 IOP Publishing Ltd.