Physics – Condensed Matter – Disordered Systems and Neural Networks
Scientific paper
2004-07-03
Physics
Condensed Matter
Disordered Systems and Neural Networks
Presented at the 1st International Discussion Meeting on Superionic Conductor Physics (Kyoto, 2003)
Scientific paper
Ion conduction in noncrystals (glasses, polymers, etc) has a number of properties in common. In fact, from a purely phenomenological point of view, these properties are even more widely observed: ion conduction behaves much like electronic conduction in disordered materials (e.g., amorphous semiconductors). These universalities are subject of much current interest, for instance interpreted in the context of simple hopping models. In the present paper we first discuss the temperature dependence of the dc conductivity in hopping models and the importance of the percolation phenomenon. Next, the experimental (quasi)universality of the ac conductivity is discussed. It is shown the random barrier model is able to reproduce the experimental finding that the response obeys time-temperature superposition, while at the same time a broad range of activation energies is involved in the conduction process. Again, percolation is the key to understanding what is going on. Finally, some open problems in the field are listed.
Dyre Jeppe C.
Schroeder Thomas B.
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