Manifestation of Random First Order Transition theory in Wigner glasses

Abstract

We use Brownian dynamics simulations of a binary mixture of highly charged spherical colloidal particles to illustrate many of the implications of the Random First Order Transition (RFOT) theory (PRA 40 1045 (1989)), which is the only theory that provides a unified description of both the statics and dynamics of the liquid to glass transition. In accord with the RFOT, we find that as the volume fraction of the colloidal particles , the natural variable that controls glass formation in colloidal systems, approaches A there is an effective ergodic to non-ergodic dynamical transition, which is signalled by a dramatic slowing down of diffusion. In addition, using the energy metric we show that the system becomes non-ergodic as A is approached. The time t*, at which the four-point dynamical susceptibility achieves a maximum, also diverges near A. Remarkably, three independent measures(translational diffusion coefficients, ergodic diffusion coefficients,as well t*) all signal that at A=0.1 ergodicity is effectively broken. The translation diffusion constant, the ergodic diffusion constant, and (t*)-1 all vanish as (A-)g with both A and g being the roughly the same for all three quantities. Below A transport involves crossing suitable free energy barriers. In this regime, the density-density correlation function decays as a stretched exponential exp(-t/taua)b with b=0.45. The -dependence of the relaxation time τa is well fit using the VFT law with the ideal glass transition occurring at K=0.47. By using an approximate measure of the local entropy (s3) we show that below A the law of large numbers, which states that the distribution of s3 for a large subsample should be identical to the whole sample, is not obeyed. The comprehensive analyses provided here for Wigner glass forming charged colloidal suspensions fully validate the concepts of the RFOT.