Condensed Matter Theory

Using electrowetting to control interface motion in patterned microchannels

(2010)

Authors:

BM Mognetti, JM Yeomans

CUDA simulations of active dumbbell suspensions

(2010)

Authors:

Victor Putz, Jorn Dunkel, Julia M Yeomans

Spin ice under pressure: symmetry enhancement and infinite order multicriticality

ArXiv 1003.4896 (2010)

Authors:

Ludovic DC Jaubert, JT Chalker, Peter CW Holdsworth, R Moessner

Abstract:

We study the low-temperature behaviour of spin ice when uniaxial pressure induces a tetragonal distortion. There is a phase transition between a Coulomb liquid and a fully magnetised phase. Unusually, it combines features of discontinuous and continuous transitions: the order parameter exhibits a jump, but this is accompanied by a divergent susceptibility and vanishing domain wall tension. All these aspects can be understood as a consequence of an emergent SU(2) symmetry at the critical point. We map out a possible experimental realisation.

Absent pinch points and emergent clusters: further neighbour interactions in the pyrochlore Heisenberg antiferromagnet

ArXiv 1003.4176 (2010)

Authors:

PH Conlon, JT Chalker

Abstract:

We discuss the origin of spin correlations observed in neutron scattering experiments on the paramagnetic phase of a number of frustrated spinel compounds, most notably ZnCr2O4. These correlations are striking for two reasons. First, they have been interpreted as evidence for the formation of weakly interacting hexagonal clusters of spins. Second, they are very different from those calculated for the nearest neighbour Heisenberg pyrochlore antiferromagnet, in which Coulomb phase correlations generate sharp scattering features known as pinch points. Using large-$n$ calculations and Monte Carlo simulations, we show that very weak further neighbour exchange interactions can account for both the apparent formation of clusters and the suppression of pinch points.

Physics and complexity.

Philos Trans A Math Phys Eng Sci 368:1914 (2010) 1175-1189

Abstract:

This paper is concerned with complex macroscopic behaviour arising in many-body systems through the combinations of competitive interactions and disorder, even with simple ingredients at the microscopic level. It attempts to indicate and illustrate the richness that has arisen, in conceptual understanding, in methodology and in application, across a large range of scientific disciplines, together with a hint of some of the further opportunities that remain to be tapped. In doing so, it takes the perspective of physics and tries to show, albeit rather briefly, how physics has contributed and been stimulated.