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结构相变物理
作者:(日)藤本 著
出版社:科学出版社
出版时间:2009-01-01
ISBN:9787030236258
定价:¥58.00
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内容简介
为了满足国内读者对国外优秀物理学著作的需求,科学出版社启动了引进国外优秀著作的工作,这些图书几乎涉及了近代物理学的所有领域,既有阐述学科基本理论的经典名著,也有反映某一学科专题前沿的专著。 本书反映的是结构相变物理领域的前沿进展和热点,具有权威性、前瞻性和应用性强的特点,对有关方向的科研人员和研究生有重要的参考价值。
作者简介
暂缺《结构相变物理》作者简介
目录
Preface to the Second Edition
Preface to the First Edition
Part I Basic Concepts
1 Thermodynamical Principles and the Landau Theory
1.1 Introduction
1.2 Phase Equilibria in Isotropic Systems
1.3 Phase Diagrams and Metastable States
1.4 The van der Waals Equation of State
1.5 Second-Order Phase Transitions and the Landau Theory
1.5.1 The Ehrenfest Classification
1.5.2 The Landau Theory
1.6 Susceptibilities and the Weiss Field
1.6.1 Susceptibility of an Order Parameter
1.6.2 The Weiss Field in a Ferromagnetic Domain
1.7 Critical Anomalies, Beyond Classical Thermodynamics
1.8 Remarks on Critical Exponents
2 Order Variables, Their Correlations and Statistics the Mean-Field Theory
2.1 Order Variables
2.2 Probabilities, Short and Long-Range Correlations, and the Mean-Field Approximation
2.2.1 Probabilities
2.2.2 The Concept of a Mean Field
2.3 Statistical Mechanics of an Order-Disorder Transition
2.4 The Ising Model for Spin-Spin Correlations
2.5 The Role of the Weiss Field in an Ordering Process
3 Collective Modes of Pseudospins in Displacive Crystals and the Born-Huang Theory
3.1 Displacive Crystals
3.2 The Landau Criterion for Classical Fluctuations
3.3 Quantum-Mechanical Pseudospins and their CorrelatiOns
3.4 The Born-Huang Theory and Structural Ordering in Crystals
3.5 Collective Pseudospin Modes in Displacive Systems
3.6 Examples of Collective Pseudospin Modes
3.6.1 Strontium Titanate and Related Perovskites
3.6.2 Tris-Sacosine Calcium Chloride and Related Crystals
3.7 The Variation Principle and the Weiss Singularity
4 Soft Modes, Lattice Anharmonicity and Pseudospin Condensates in the Critical Region
4.1 The Critical Modulation
4.2 The Lyddane-Sachs-Teller Relation
4.3 Long-Range Interactions and the Cochran Theory
4.4 The Quartic Anharmonic Potential in the Critical Region
4.4.1 The Cowley Theory of Mode Softening
4.4.2 Symmetry Change at a Continuous Phase Transition
4.5 Observation of Soft-Mode Spectra
4.6 The Central Peak
4.7 Symmetry-Breaking Fluctuations in Binary Phase Transitions
4.8 Macroscopic Observation of a Binary Phase Transition;λ-anomaly of the Specific Heat
5 Dynamics of Pseudospins Condensates and the Long-Range Order
5.1 Imperfections in Practical Crystals
5.2 The Pinning Potential .
5.3 The Lifshitz Condition for Incommensurate Fluctuations
5.4 A Pseudopotential for Condensate Locking and Commensurate Modulation
5.5 Propagation of a Collective Pseudospin Mode
5.6 A Hydrodynamic Model for Pseudospin Propagation
5.7 The Korteweg-deVries Equation
5.7.1 General Derivation
5.7.2 Solutions of the Korteweg-deVries Equation
5.8 Soliton Potentials and the Long-Range Order
5.9 Mode Stabilization by the Eckart Potential
Part II Experimental Studies
6 Diffuse X-ray Diffraction and Neutron Inelastic Scattering from Modulated Crystals
6.1 Modulated Crystals
6.2 The Bragg Law of X-ray Diffraction
6.3 Diffuse Diffraction from Weakly Modulated Crystals
6.4 The Laue Formula and Diffuse Diffraction from Perovskites
6.5 Neutron Inelastic Scattering
7 Light Scattering and Dielectric Studies on Structural Phase Transitions
7.1 Raman Scattering Studies on Structural Transitions
7.2 Rayleigh and Brillouin Scatterings
7.3 Dielectric Relaxation
7.4 Dielectric Spectra in the Ferroelectric Phase Transition of TSCC
8 The Spin-Hamiltonian and Magnetic Resonance Spectroscopy
8.1 Introduction
8.2 Principles of Magnetic Resonance and Relaxation
8.3 Magnetic Resonance Spectrometers
8.4 The Crystalline Potential
8.5 The Zeeman Energy and the g Tensor
8.6 The Fine Structure
8.7 Hyperfine Interactions and Forbidden Transitions
9 Magnetic Resonance Sampling and Nuclear Spin Relaxation Studies on Modulated Crystals
9.1 Paramagnetic Probes in a Modulated Crystal
9.2 The spin-Hamiltonian in Modulated Crystals
9.2.1 The g Tensor Anomaly
9.2.2 The Hyperfine Structure Anomaly
9.2.3 The Fine-Structure Anomaly
9.3 Structural Phase Transitions in TSCC and BCCD Crystals as Studied by Paramagnetic Resonance Spectra
9.3.1 The Ferroelectric Phase Transition in TSCC Crystals
9.3.2 Structural Phase Transitions in BCCD Crystals
9.4 Nuclear Quadrupole Relaxation in Incommensurate Phases
10 Structural Phase Transitions in Miscellaneous Systems
10.1 Cell-Doubling Transitions in Oxide Perovskites
10.2 The Incommensurate Phase in β-Thorium Tetrabromide
10.3 Phase Transitions in Deuterated Biphenyl Crystals
10.4 Successive Phase Transitions in A2BX4 Family Crystals
10.5 Incommensurate Phases in RbH3(SeO3)2 and Related Crystals
10.6 Phase Transitions in (NH4)2SO4 and NH4AlF4
10.7 Proton Ordering in Hydrogen-Bonded Crystals
Epilogue
Appendix The Adiabatic Approximation
Index
Preface to the First Edition
Part I Basic Concepts
1 Thermodynamical Principles and the Landau Theory
1.1 Introduction
1.2 Phase Equilibria in Isotropic Systems
1.3 Phase Diagrams and Metastable States
1.4 The van der Waals Equation of State
1.5 Second-Order Phase Transitions and the Landau Theory
1.5.1 The Ehrenfest Classification
1.5.2 The Landau Theory
1.6 Susceptibilities and the Weiss Field
1.6.1 Susceptibility of an Order Parameter
1.6.2 The Weiss Field in a Ferromagnetic Domain
1.7 Critical Anomalies, Beyond Classical Thermodynamics
1.8 Remarks on Critical Exponents
2 Order Variables, Their Correlations and Statistics the Mean-Field Theory
2.1 Order Variables
2.2 Probabilities, Short and Long-Range Correlations, and the Mean-Field Approximation
2.2.1 Probabilities
2.2.2 The Concept of a Mean Field
2.3 Statistical Mechanics of an Order-Disorder Transition
2.4 The Ising Model for Spin-Spin Correlations
2.5 The Role of the Weiss Field in an Ordering Process
3 Collective Modes of Pseudospins in Displacive Crystals and the Born-Huang Theory
3.1 Displacive Crystals
3.2 The Landau Criterion for Classical Fluctuations
3.3 Quantum-Mechanical Pseudospins and their CorrelatiOns
3.4 The Born-Huang Theory and Structural Ordering in Crystals
3.5 Collective Pseudospin Modes in Displacive Systems
3.6 Examples of Collective Pseudospin Modes
3.6.1 Strontium Titanate and Related Perovskites
3.6.2 Tris-Sacosine Calcium Chloride and Related Crystals
3.7 The Variation Principle and the Weiss Singularity
4 Soft Modes, Lattice Anharmonicity and Pseudospin Condensates in the Critical Region
4.1 The Critical Modulation
4.2 The Lyddane-Sachs-Teller Relation
4.3 Long-Range Interactions and the Cochran Theory
4.4 The Quartic Anharmonic Potential in the Critical Region
4.4.1 The Cowley Theory of Mode Softening
4.4.2 Symmetry Change at a Continuous Phase Transition
4.5 Observation of Soft-Mode Spectra
4.6 The Central Peak
4.7 Symmetry-Breaking Fluctuations in Binary Phase Transitions
4.8 Macroscopic Observation of a Binary Phase Transition;λ-anomaly of the Specific Heat
5 Dynamics of Pseudospins Condensates and the Long-Range Order
5.1 Imperfections in Practical Crystals
5.2 The Pinning Potential .
5.3 The Lifshitz Condition for Incommensurate Fluctuations
5.4 A Pseudopotential for Condensate Locking and Commensurate Modulation
5.5 Propagation of a Collective Pseudospin Mode
5.6 A Hydrodynamic Model for Pseudospin Propagation
5.7 The Korteweg-deVries Equation
5.7.1 General Derivation
5.7.2 Solutions of the Korteweg-deVries Equation
5.8 Soliton Potentials and the Long-Range Order
5.9 Mode Stabilization by the Eckart Potential
Part II Experimental Studies
6 Diffuse X-ray Diffraction and Neutron Inelastic Scattering from Modulated Crystals
6.1 Modulated Crystals
6.2 The Bragg Law of X-ray Diffraction
6.3 Diffuse Diffraction from Weakly Modulated Crystals
6.4 The Laue Formula and Diffuse Diffraction from Perovskites
6.5 Neutron Inelastic Scattering
7 Light Scattering and Dielectric Studies on Structural Phase Transitions
7.1 Raman Scattering Studies on Structural Transitions
7.2 Rayleigh and Brillouin Scatterings
7.3 Dielectric Relaxation
7.4 Dielectric Spectra in the Ferroelectric Phase Transition of TSCC
8 The Spin-Hamiltonian and Magnetic Resonance Spectroscopy
8.1 Introduction
8.2 Principles of Magnetic Resonance and Relaxation
8.3 Magnetic Resonance Spectrometers
8.4 The Crystalline Potential
8.5 The Zeeman Energy and the g Tensor
8.6 The Fine Structure
8.7 Hyperfine Interactions and Forbidden Transitions
9 Magnetic Resonance Sampling and Nuclear Spin Relaxation Studies on Modulated Crystals
9.1 Paramagnetic Probes in a Modulated Crystal
9.2 The spin-Hamiltonian in Modulated Crystals
9.2.1 The g Tensor Anomaly
9.2.2 The Hyperfine Structure Anomaly
9.2.3 The Fine-Structure Anomaly
9.3 Structural Phase Transitions in TSCC and BCCD Crystals as Studied by Paramagnetic Resonance Spectra
9.3.1 The Ferroelectric Phase Transition in TSCC Crystals
9.3.2 Structural Phase Transitions in BCCD Crystals
9.4 Nuclear Quadrupole Relaxation in Incommensurate Phases
10 Structural Phase Transitions in Miscellaneous Systems
10.1 Cell-Doubling Transitions in Oxide Perovskites
10.2 The Incommensurate Phase in β-Thorium Tetrabromide
10.3 Phase Transitions in Deuterated Biphenyl Crystals
10.4 Successive Phase Transitions in A2BX4 Family Crystals
10.5 Incommensurate Phases in RbH3(SeO3)2 and Related Crystals
10.6 Phase Transitions in (NH4)2SO4 and NH4AlF4
10.7 Proton Ordering in Hydrogen-Bonded Crystals
Epilogue
Appendix The Adiabatic Approximation
Index
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