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Density Waves in Solids [Kietas viršelis]

  • Formatas: Hardback, 288 pages, aukštis x plotis: 232x162 mm, weight: 520 g, Illustrations
  • Serija: Frontiers in Physics
  • Išleidimo metai: 20-Apr-1994
  • Leidėjas: Perseus Books
  • ISBN-10: 0201626543
  • ISBN-13: 9780201626544
Kitos knygos pagal šią temą:
Density Waves in Solids
  • Formatas: Hardback, 288 pages, aukštis x plotis: 232x162 mm, weight: 520 g, Illustrations
  • Serija: Frontiers in Physics
  • Išleidimo metai: 20-Apr-1994
  • Leidėjas: Perseus Books
  • ISBN-10: 0201626543
  • ISBN-13: 9780201626544
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9780201626544.html
Raktažodžiai:
Discusses the theoretical and experimental side of two novel types of broken symmetry ground states of metals, charge, and spin density waves. These states arise as the consequence of electron-phonon and electron-electron interactions in low-dimensional metals. Topics include fundamental aspects of the one-dimensional gas, materials with anisotropic properties, the mean field theory of phase transitions, fluctuation effects and collective excitations, interactions with the underlying lattice and impurities, and the response of ground states to external perturbations. Annotation copyright Book News, Inc. Portland, Or.

”Density Waves in Solids is written for graduate students and scientists interested in solid-state sciences. It discusses the theoretical and experimental state of affairs of two novel types of broke


”Density Waves in Solids is written for graduate students and scientists interested in solid-state sciences. It discusses the theoretical and experimental state of affairs of two novel types of broken symmetry ground states of metals, charge, and spin density waves. These states arise as the consequence of electron-phonon and electron-electron interactions in low-dimensional metals.Some fundamental aspects of the one-dimensional electron gas, and of the materials with anisotropic properties, are discussed first. This is followed by the mean field theory of the phases transitions—discussed using second quantized formalism—together with the various experimental observations on the transition and on the ground states. Fluctuation effects and the collective excitations are reviewed next, using the Ginzburg-Landau formalism, followed by the review of the interaction of these states with the underlying lattice and with impurities. The final chapters are devoted to the response of the ground states to external perturbations.
Notation Legend xv
Preface xix
The One-Dimensional Electron Gas
1(14)
The Response Function of the One-Dimensional Electron Gas
1(7)
Instabilities in a One-Dimensional Electron Gas: g-ology
8(5)
Correlations and Fluctuations
13(2)
Materials
15(16)
Inorganic Linear Chain Compounds
18(7)
Organic Linear Chain Compounds
25(6)
The Charge Density Wave Transition and Ground State: Mean Field Theory and Some Basic Observations
31(40)
The Kohn Anomaly and the Peierls Transition: Mean Field Theory
32(18)
Single Particle Transitions: Tunneling and Coherence Factors
50(5)
Experimental Evidences for the Charge Density Wave Transition and Ground State
55(16)
The Spin Density Wave Transition and Ground State: Mean Field Theory and Some Basic Observations
71(15)
Mean Field Theory of the Spin Density Wave Transition
72(7)
Experimental Evidences for the Spin Density Wave Transition and Ground State
79(7)
Fluctuation Effects
86(20)
Fluctuations in Quasi-One-Dimensional Metals
87(14)
Charge Density Wave Fluctuations in K0.3MoO3
101(5)
Collective Excitations
106(30)
Ginzburg-Landau Theory of Charge Density Wave Excitations
108(16)
Excitations of the Spin Density Wave Ground State
124(3)
Experiments on Charge Density Waves: Neutron and Raman Scattering
127(5)
Experiments on Spin Density Waves: AFMR and Magnetization
132(4)
Commensurability and Near Commensurability Effects
136(14)
Models of Commensurability Effects
137(10)
Experiments: Search for Commensurability Effects and Solitons
147(3)
The Interaction Between Density Waves and Impurities
150(14)
Theories of Density Wave-Impurity Interaction
151(7)
Experimental Evidence for Finite Correlation Lengths
158(6)
The Electrodynamics of Density Waves
164(18)
The Electrodynamics of Density Waves
165(9)
Frequency Dependent Conductivity of Charge Density Waves
174(5)
Frequency Dependent Conductivity of Spin Density Waves
179(3)
Nonlinear Transport
182(16)
Models of Density Wave Transport
183(9)
Experiments on the Nonlinear Dynamics of the Collective Modes
192(6)
Current Oscillations and Interference Effects in Driven Charge Density Wave Condensates (Reprinted in part from Progress in Low Temperature Physics, vol. XII. Ed.: D.F. Brewer, Elsevier Publishers, B.V. 1989).
198(46)
Introduction
198(2)
Current Oscillations
200(12)
Interference Phenomena
212(27)
Conclusions
239(5)
References 244(8)
Some Books, Conference Proceedings, and Review Papers. 252(2)
Index 254