α-relaxation near the glass transition

L. Sjörgen; W. Götze

doi:10.1016/0022-3093(91)90291-D

α-relaxation near the glass transition

L. Sjörgen, W. Götze

TUM Emeriti of Excellence

Institute of Theoretical Physics, Goteborg

Research output: Contribution to journal › Article › peer-review

32 Scopus citations

Abstract

The general mode-coupling equations with activated processes included are analysed in the α-relaxation region. This region is intimately connected with the β-relaxation region, where dynamics is completely ruled by generic properties of various bifurcation singularities inherent in the nonlinear equations of motion. In particular the von Schweidler relaxation, which describes the overlap region between the α- and β-processes, plays a central role for the properties of the α-relaxation function. This satisfies the time-temperature superposition principle with a master function which is well described by a Kohlrausch law. The α-relaxation scale is proportional to the macroscopic viscosity, and for the temperature dependence one finds an algebraic increase above a critical temperature T_c, i.e. η∝(T-T_c)^-γ. For lower temperatures, there is eventually a crossover to an Arrhenius law η∝ exp(E/k_BT).

Original language	English
Pages (from-to)	153-160
Number of pages	8
Journal	Journal of Non-Crystalline Solids
Volume	131-133
Issue number	PART 1
DOIs	https://doi.org/10.1016/0022-3093(91)90291-D
State	Published - 11 Jun 1991

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title = "α-relaxation near the glass transition",

abstract = "The general mode-coupling equations with activated processes included are analysed in the α-relaxation region. This region is intimately connected with the β-relaxation region, where dynamics is completely ruled by generic properties of various bifurcation singularities inherent in the nonlinear equations of motion. In particular the von Schweidler relaxation, which describes the overlap region between the α- and β-processes, plays a central role for the properties of the α-relaxation function. This satisfies the time-temperature superposition principle with a master function which is well described by a Kohlrausch law. The α-relaxation scale is proportional to the macroscopic viscosity, and for the temperature dependence one finds an algebraic increase above a critical temperature Tc, i.e. η∝(T-Tc)-γ. For lower temperatures, there is eventually a crossover to an Arrhenius law η∝ exp(E/kBT).",

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AB - The general mode-coupling equations with activated processes included are analysed in the α-relaxation region. This region is intimately connected with the β-relaxation region, where dynamics is completely ruled by generic properties of various bifurcation singularities inherent in the nonlinear equations of motion. In particular the von Schweidler relaxation, which describes the overlap region between the α- and β-processes, plays a central role for the properties of the α-relaxation function. This satisfies the time-temperature superposition principle with a master function which is well described by a Kohlrausch law. The α-relaxation scale is proportional to the macroscopic viscosity, and for the temperature dependence one finds an algebraic increase above a critical temperature Tc, i.e. η∝(T-Tc)-γ. For lower temperatures, there is eventually a crossover to an Arrhenius law η∝ exp(E/kBT).

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α-relaxation near the glass transition

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