Luis Enrique Sanchez-Diaz, Pedro Ramirez-Gonzalez, Magdaleno Medina-Noyola
The recently-developed non-equilibrium extension of the self-consistent generalized Langevin equation theory of irreversible relaxation [Phys. Rev. E (2010) 82, 061503; ibid. 061504] is applied to the description of the irreversible process of equilibration and aging of a glass-forming soft-sphere liquid that follows a sudden temperature quench, within the constraint that the local mean particle density remains uniform and constant. For these particular conditions, this theory describes the non-equilibrium evolution of the static structure factor S(k;t) and of the dynamic properties, such as the self-intermediate scattering function F_S(k,\tau;t), where tau is the correlation delay time and t is the evolution or waiting time after the quench. Specific predictions are presented, for the deepest quench (to zero temperature). The predicted evolution of the alpha-relaxation time \tau_\alpha(t) as a function of t allows us to define the equilibration time t^{eq}, as the time after which \tau_\alpha has attained its equilibrium value \tau_\alpha^{eq}. It is predicted that both, t^{eq}(\phi) and \tau_{\alpha}^{eq}, diverge as \phi \to \phi^{(a)}, where \phi^{(a)} is the hard-sphere dynamic-arrest volume fraction \phi^{(a)}\ (\approx 0.582), thus suggesting that the measurement of equilibrium properties at and above \phi^{(a)} is experimentally impossible.
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http://arxiv.org/abs/1211.6806
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