Influence of the cooling-rate on the glass transition temperature and the structural properties of glassy GeS2: an ab initio molecular dynamics study
Abstract
Using density-functional molecular dynamics simulations we analyzed the cooling-rate effects on the physical properties of GeS2 chalcogenide glasses. Liquid samples were cooled linearly in time according to T(t) = T0 - γ t where γ is the cooling rate. We found that our model leads to a promising description of the glass transition temperature Tg as a function of γ and gives a correct Tg for experimental cooling rates. We also investigated the dependence of the structural properties on the cooling rate. We show that, globally, the properties determined from our simulations are in good agreement with experimental values and this even for the highest cooling rates. In particular, our results confirm that, in the range of cooling rates studied here, homopolar bonds and extended charged regions are always present in the glassy phase. Nevertheless in order to reproduce the experimental intermediate range order of the glass, a maximum cooling rate should not be exceeded in numerical simulations.
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