| Kommentar |
<p><strong>Structure of the lecture course</strong></p><p><span lang="EN-US" style="font-family: 'Abyssinica SIL';">1. Overview</span></p><p> </p><p>2.1 Silicates and Borates</p><p>2.2 Polymers</p><p>2.3 Orcanic Semiconductors</p><p><strong> </strong></p><p>3.1 Quenching from the melt</p><p>3.2 Deposition onto substrates</p><p> </p><p>4.1 Liquid structure and molecular distribution</p><p>4.2 Gelation and Network models</p><p> </p><p>5.1 Maxwell viscoelasticity</p><p>5.2 Glass transition as very-slow relaxation limit</p><p>5.3 Thermal properties and Kauzmann pradox</p><p> </p><p>6.1 Adam-Gibbs model</p><p>6.2 Mode-coupling theory</p><p>6.3 Spin glasses and Potts models</p><p>6.4 Dynamical facilitation</p><p>6.5 Replica theory</p><p> </p><p>7.1 Phenomenoloty: Jonscher ω<sup>S</sup> law for the AC conductivity</p><p>7.2 Coherent-potential approximation</p><p> </p><p>8.1 Experimental methods, boson peak</p><p>8.2 Various models for the boson peak</p><p>8.3 Mathematical analogy between AC conductivity and anomalous vibrations</p><p>8.4 Heterogeneous-elasticity theory</p><p>8.5 Theory of low-frequency Raman scattering</p> |
