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Based on a microscopic theory developed recently, a dynamical model of density fluctuations in simple fluids and glasses is proposed and analyzed analytically and numerically. The model exhibits a liquid-glass transition, where the glassy phase is characterized by a zero-frequency pole of the longitudinal and transverse viscosities indicating the systems' stability against stress. This also implies an elastic peak in the density-fluctuation spectrum. Approaching the glass transition the slowing down of density fluctuations is controlled by the increasing longitudinal viscosity, which in turn is coupled via a nonlinear feedback mechanism to the slowly decaying density fluctuations. This causes a divergence of the structural relaxation time at a certain critical coupling constant ₂. At the glass transition density fluctuations decay with a long-time power law (t) t^- with =0. 395 and approaching the transition the viscosity diverges proportional to ^- and ^-, where =|1-{₂}| and = (1+) 2, ^'=-1 below and above the transition, respectively. The long-time tail "paradox" in dense fluids is briefly discussed.
E. Leutheusser (Tue,) studied this question.
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