Condensed Matter Theory

The stability of a crystal with diamond structure for patchy particles with tetrahedral symmetry

ArXiv 1005.5019 (2010)

Authors:

Eva G Noya, Carlos Vega, Jonathan PK Doye, Ard A Louis

Abstract:

The phase diagram of model anisotropic particles with four attractive patches in a tetrahedral arrangement has been computed at two different values for the range of the potential, with the aim of investigating the conditions under which a diamond crystal can be formed. We find that the diamond phase is never stable for our longer-ranged potential. At low temperatures and pressures, the fluid freezes into a body-centred-cubic solid that can be viewed as two interpenetrating diamond lattices with a weak interaction between the two sublattices. Upon compression, an orientationally ordered face-centred-cubic crystal becomes more stable than the body-centred-cubic crystal, and at higher temperatures a plastic face-centered-cubic phase is stabilized by the increased entropy due to orientational disorder. A similar phase diagram is found for the shorter-ranged potential, but at low temperatures and pressures, we also find a region over which the diamond phase is thermodynamically favored over the body-centred-cubic phase. The higher vibrational entropy of the diamond structure with respect to the body-centred-cubic solid explains why it is stable even though the enthalpy of the latter phase is lower. Some preliminary studies on the growth of the diamond structure starting from a crystal seed were performed. Even though the diamond phase is never thermodynamically stable for the longer-ranged model, direct coexistence simulations of the interface between the fluid and the body-centred-cubic crystal and between the fluid and the diamond crystal show that, at sufficiently low pressures, it is quite probable that in both cases the solid grows into a diamond crystal, albeit involving some defects. These results highlight the importance of kinetic effects in the formation of diamond crystals in systems of patchy particles.

The stability of a crystal with diamond structure for patchy particles with tetrahedral symmetry

(2010)

Authors:

Eva G Noya, Carlos Vega, Jonathan PK Doye, Ard A Louis

The effect of scale-free topology on the robustness and evolvability of genetic regulatory networks

(2010)

Authors:

Sam F Greenbury, Iain G Johnston, Matthew A Smith, Jonathan PK Doye, Ard A Louis

Is Water an Amniotic Eden or a Corrosive Hell? Emerging Perspectives on the Strangest Fluid in the Universe

Chapter in Water and Life, Taylor & Francis (2010) 3-9

Authors:

Simon Morris, Ard Louis

Lattice boltzmann simulations of wetting and drop dynamics

Understanding Complex Systems 2010 (2010) 241-274

Authors:

H Kusumaatmaja, JM Yeomans

Abstract:

Recently there has been a huge effort in the scientific community to miniaturise fluidic operations to micron and nanoscales [1]. This has changed the way scientists think about fluids, and it potentially has far-reaching technological implications, analogous to the miniaturization of electronics. The goal is to engineer "lab on a chip" devices, where numerous biological and chemical experiments can be performed rapidly, and in parallel, while consuming little reagent. © 2010 Springer-Verlag Berlin Heidelberg.