Condensed Matter Theory

Propulsion of a molecular machine by asymmetric distribution of reaction products.

Phys Rev Lett 94:22 (2005) 220801

Authors:

Ramin Golestanian, Tanniemola B Liverpool, Armand Ajdari

Abstract:

A simple model for the reaction-driven propulsion of a small device is proposed as a model for (part of) a molecular machine in aqueous media. The motion of the device is driven by an asymmetric distribution of reaction products. The propulsive velocity of the device is calculated as well as the scale of the velocity fluctuations. The effects of hydrodynamic flow as well as a number of different scenarios for the kinetics of the reaction are addressed.

Transport between edge states in multilayer integer quantum Hall systems: exact treatment of Coulomb interactions and disorder

ArXiv cond-mat/0506223 (2005)

Authors:

JW Tomlinson, J-S Caux, JT Chalker

Abstract:

A set of stacked two-dimensional electron systems in a perpendicular magnetic field exhibits a three-dimensional version of the quantum Hall effect if interlayer tunneling is not too strong. When such a sample is in a quantum Hall plateau, the edge states of each layer combine to form a chiral metal at the sample surface. We study the interplay of interactions and disorder in transport properties of the chiral metal, in the regime of weak interlayer tunneling. Our starting point is a system without interlayer tunneling, in which the only excitations are harmonic collective modes: surface magnetoplasmons. Using bosonization and working perturbatively in the interlayer tunneling amplitude, we express transport properties in terms of the spectrum for these collective modes, treating electron-electron interactions and impurity scattering exactly. We calculte the conductivity as a function of temperature, finding that it increases with increasing temperature as observed in recent experiments. We also calculate the autocorrelation function of mesoscopic conductance fluctuations induced by changes in a magnetic field component perpendicular to the sample surface, and its dependence on temperature. We show that conductance fluctuations are characterised by a dephasing length that varies inversely with temperature.

Droplet dynamics on patterned substrates

PRAMANA-J PHYS 64:6 (2005) 1019-1027

Authors:

A Dupuis, JM Yeomans

Abstract:

We present a lattice Boltzmann algorithm which can be used to explore the spreading of droplets on chemically and topologically patterned substrates. As an example we use the method to show that the final configuration of a drop on a substrate comprising hydrophobic and hydrophilic stripes can depend sensitively on the dynamical pathway by which the state is reached. We also consider a substrate covered with micron-scale posts and investigate how this can lead to superhydrophobic behaviour. Finally we model how a Namibian desert beetle collects water from the wind.

GLASSY BEHAVIOR DUE TO KINETIC CONSTRAINTS: FROM TOPOLOGICAL FOAM TO BACKGAMMON

Chapter in Current Topics in Physics, World Scientific Publishing (2005) 151-174

Kinetics of the polymer collapse transition: the role of hydrodynamics.

Phys Rev E Stat Nonlin Soft Matter Phys 71:6 Pt 1 (2005) 061804

Authors:

N Kikuchi, JF Ryder, CM Pooley, JM Yeomans

Abstract:

We investigate numerically the dynamical behavior of a polymer chain collapsing in a dilute solution. The rate of collapse is measured with and without the presence of hydrodynamic interactions. We find that hydrodynamic interactions accelerate polymer collapse. We present a scaling theory describing the physical process responsible for the collapse kinetics. Predicted collapse times in a hydrodynamic (tauH approximately N(4/3)) and a Brownian heat bath (tauB approximately N2) agree well with the numerical results (tauH approximately N(1.40+/-0.08) and tauB approximately N(1.89+/-0.09)) where N denotes chain length. The folding kinetics of Go models of proteins is also examined. We show that for these systems, where many free energy minima compete, hydrodynamics has little effect on the kinetics.