Charge Density Waves in Solids
The latest addition to this series covers a field which is commonly referred to as charge density wave dynamics. The most thoroughly investigated materials are inorganic linear chain compounds with highly anisotropic electronic properties. The volume opens with an examination of their structural properties and the essential features which allow charge density waves to develop. The behaviour of the charge density waves, where interesting phenomena are observed, is treated both from a theoretical and an experimental standpoint. The role of impurities in statics and dynamics is considered and an examination of the possible role of solitons in incommensurate charge density wave systems is given. A number of ways to describe charge density waves theoretically, using computer simulations as well as microscopical models, are presented by a truely international board of authors.
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a bridged MX3 structure
The particular case of TaTe4 and NbTe4
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2fcF amplitude Artemenko band behavior blue bronze Borodin CDW current CDW phase chain direction chalcogen Charge Density Waves circle map coherence coherence length collective mode condensate configuration Coppersmith correlation length corresponding coupling crystal decrease deformations degrees of freedom dielectric distortion domain dynamics effects elastic electric field electron equations experimental Fermi surface finite Fleming FLR model fluctuations frequency function Gor'kov Griiner harmonic hysteretic impurity pinning incommensurate interaction lattice Lett Littlewood low temperatures measured Meerschaut metal metastable Mihaly mode locking modulation Monceau monoclinic Mozurkewich NbSe3 noise observed obtained order parameter orthorhombic Peierls transition period phase slip phase transition phason phonon Phys Phys.-JETP potential Pouget properties pulse quasiparticle region response Rouxel sample scattering Schneemeyer shown in fig shows single-particle Sneddon Solid State Commun soliton solution spectrum structure superconducting TaS3 TCNQ temperature dependence threshold field TTF-TCNQ velocity voltage wave vector Zettl
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Heterogeneous Materials: Nonlinear and Breakdown Properties and ..., Volume 2
No preview available - 2003