Condensed Matter Theory

Zigzag transitions and nonequilibrium pattern formation in colloidal chains

ArXiv 1309.3442 (2013)

Authors:

Arthur V Straube, Roel PA Dullens, Lutz Schimansky-Geier, Ard A Louis

Abstract:

Paramagnetic colloidal particles that are optically trapped in a linear array can form a zigzag pattern when an external magnetic field induces repulsive interparticle interactions. When the traps are abruptly turned off, the particles form a nonequilibrium expanding pattern with a zigzag symmetry, even when the strength of the magnetic interaction is weaker than that required to break the linear symmetry of the equilibrium state. We show that the transition to the equilibrium zigzag state is always potentially possible for purely harmonic traps. For anharmonic traps that have a finite height, the equilibrium zigzag state becomes unstable above a critical anharmonicity. A normal mode analysis of the equilibrium line configuration demonstrates that increasing the magnetic field leads to a hardening and softening of the spring constants in the longitudinal and transverse directions, respectively. The mode that first becomes unstable is the mode with the zigzag symmetry, which explains the symmetry of nonequilibrium patterns. Our analytically tractable models help to give further insight into the way that the interplay of such factors as the length of the chain, hydrodynamic interactions, thermal fluctuations affect the formation and evolution of the experimentally observed nonequilibrium patterns.

Zigzag transitions and nonequilibrium pattern formation in colloidal chains

(2013)

Authors:

Arthur V Straube, Roel PA Dullens, Lutz Schimansky-Geier, Ard A Louis

Viscous fingering at ultralow interfacial tension

(2013)

Authors:

Siti Aminah Setu, Ioannis Zacharoudiou, Gareth J Davies, Denis Bartolo, Sebastien Moulinet, Ard A Louis, Julia M Yeomans, Dirk GAL Aarts

Length Distributions in Loop Soups

Physical Review Letters American Physical Society (APS) 111:10 (2013) 100601

Authors:

Adam Nahum, JT Chalker, P Serna, M Ortuño, AM Somoza

Coarse-graining DNA for simulations of DNA nanotechnology

ArXiv 1308.3843 (2013)

Authors:

Jonathan PK Doye, Thomas E Ouldridge, Ard A Louis, Flavio Romano, Petr Sulc, Christian Matek, Benedict EK Snodin, Lorenzo Rovigatti, John S Schreck, Ryan M Harrison, William PJ Smith

Abstract:

To simulate long time and length scale processes involving DNA it is necessary to use a coarse-grained description. Here we provide an overview of different approaches to such coarse graining, focussing on those at the nucleotide level that allow the self-assembly processes associated with DNA nanotechnology to be studied. OxDNA, our recently-developed coarse-grained DNA model, is particularly suited to this task, and has opened up this field to systematic study by simulations. We illustrate some of the range of DNA nanotechnology systems to which the model is being applied, as well as the insights it can provide into fundamental biophysical properties of DNA.