Charge-density-waves

Ceroplastol synthesis, 1, 428 Cetyl alcohol synthesis, 1, 478 Chaetoglobasins structures, 4, 376 Chalcone, o -azido-2 -oxy-synthesis, 3, 823 Chalcone, 2-hydroxy-reduction, 3, 751 Chalcone, 2 -hydroxy-mass spectra, 3, 618 Chalcone dibromides flavone synthesis from, 3, 823 Chalcones polymers, 1, 304 Chanoclavine synthesis, 6, 423 Charge density waves in stacks of ions, 1, 351-352 Chartreusin... [Pg.577]

Platinacyclopent-2-ene-4,5-diones synthesis, 1, 669 Platinates, tetracyano-charge density waves in, 1, 352 Platinum... [Pg.747]

T. Emig, T. Nattermann. Disorder-driven roughening transition of charge-density waves and flux-Unes. Phys Rev Lett 79 5090, 1997 T. Emig, Th. [Pg.917]

In what follows we will discuss systems with internal surfaces, ordered surfaces, topological transformations, and dynamical scaling. In Section II we shall show specific examples of mesoscopic systems with special attention devoted to the surfaces in the system—that is, periodic surfaces in surfactant systems, periodic surfaces in diblock copolymers, bicontinuous disordered interfaces in spinodally decomposing blends, ordered charge density wave patterns in electron liquids, and dissipative structures in reaction-diffusion systems. In Section III we will present the detailed theory of morphological measures the Euler characteristic, the Gaussian and mean curvatures, and so on. In fact, Sections II and III can be read independently because Section II shows specific models while Section III is devoted to the numerical and analytical computations of the surface characteristics. In a sense, Section III is robust that is, the methods presented in Section III apply to a variety of systems, not only the systems shown as examples in Section II. Brief conclusions are presented in Section IV. [Pg.143]

Charge density wave (CDW) materials are among the well-established... [Pg.54]

Charge density wave, 54 Charge spreading, 127 Charge-resonant states, 13, 18 Charge-asymmetric dissociation, 9 Coherent control, 7... [Pg.209]

The situation discussed here is equivalent to a periodic distortion of the lattice with a period 2a, as developed above. When the perturbation //per is given by lattice vibrations, that is mediated by electron-phonon interactions, the electronic density modulation is expressed in terms of a charge-density wave (CDW), while when electron-electron repulsions dominate the modulation is induced by SDWs (Canadell Whangbo, 1991). [Pg.77]

One-dimensional electrical conductors, platinum complexes, 26 235-268 band theory, 26 237-241 charge density waves, 26 239-240 Kahn-Teller effect, 26 239-240 and superconductivity, 26 240-241 One-electron reactions, oxo-molybdenum centers, 40 56-57... [Pg.212]

Drozdova O, Yakushi K, Yamamoto K, Ota A, Yamochi H, Saito G, Tashiro H, Tanner DB (2004) Optical characterization of 2kp bond-charge-density wave in quasi-one-dimensional 3/4-filled (ED0-TTF)2X (X = PFg and AsFg). Phys Rev B70 075107-1/8... [Pg.116]

Barrett, R. C. Nogami, J., and Quate, C. F. (1990). Charge density waves of IT TaS2 imaged by atomic force microscopy. Appl. Phys. Lett. 57, 992-994. [Pg.384]

Coleman, R. V., Drake, B., Hansma, P. K., and Slough, G. (1985). Charge-density waves observed with a tunnehng microscope. Phys. Rev. Lett. 55, 394-397. [Pg.388]

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