正版 材料物理双语教程 密保秀,高志强 人民邮电出版社 978711545

Chapter 1 Introduction
1.1 Definition of Material
1.2 Family of Materials
1.3 Brief History of Material Development
1.4 Material Physics and Other Related Science
1.5 Importance of Material Science
Vocabulary
Problems
Chapter 2 Basic Structure and Organization of Atoms in a Material
2.1 Bonding Modes Among Atoms
2.2 Crystal Structure
2.2.1 Unit Cells, Space Lattices and Lattice Point
2.2.2 Crystal Systems
2.2.3 Representative Parameters for Crystal Systems
2.2.4 Crystal Structures of Metals and Organic Materials
2.3 Crystal Defects
2.4 Nanocrystalline Structures
2.5 Amorphous Structures
Vocabulary
Problems
Chapter 3 Fundamentals of Electron Theory
3.1 Introduction
3.2 Wave Particle Duality and Quantum Mechanics
3.3 Wave Function and Schrodinger Equation
3.4 Classical and Quantum Statistics
3.5 Free Electron Theory of Metals
3.6 Band Theory of Solids
3.6.1 Schr6dinger Equation and Its Solution Under near Free Electron Approximation
3.6.2 Bandgap
3.6.3 Interpretation of Conductivity
3.6.4 Brillouin Zone Under Near Free Electron Approximate
3.6.5 State Density under Band Theory
3.6.6 Effective Electron Mass as a Function of k
Vocabulary
Problems
Chapter 4 Solid State Phase Transformation
4.1 Concepts
4.2 Features of Solid State Phase Transformation
4.2.1 General Procedure
4.2.2 Phase Interface
4.2.3 Orientation Relationship
4.2.4 Habit Plane
4.2.5 Strain Energy
4.2.6 Influence of Defects
4.2.7 Atom Diffusion
4.3 Classification of Solid State Phase Transformation
4.3.1 Classification Based on Thermodynamics
4.3.2 Classification Based on Atomic Diffusion
4.4 Polycrystalline Transformation
4.5 Eutectoid Transformation
4.5.1 Thermodynamics of Eutectoid Transformation
4.5.2 Processes in Eutectoid Transformation
4.5.3 Dynamic Characteristics: TTTCurve
4.6 Austenite-Martensite Transformation
4.6.1 Historical Remark
4.6.2 Features of Martensitic Transformation
4.6.3 Dynamic Process
4.6.4 Shapes of Martensite
4.6.5 The Mechanism of Martensite Formation
4.6.6 Thermoelastic Martensite and Shape Memory Effect
4.7 Glass Transition
Vocabulary
Problems
Chapter 5 Mechanical Properties
5.1 Significance of Material Mechanical Properties
5.2 Basic Concepts in Mechanics
5.3 Elastic Deformation
5.4 Plastic Deformation
5.5 Creep and Stress Relaxation
5.6 Fracture and Fatigue
Vocabulary
Problems
Chapter 6 Electrical Properties
6.1 Basic Concepts for Electricity
6.1.1 OhmsLaw
6.1.2 Conductivity
6.1.3 Mean Free Path
6.1.4 Materials with Different Electrical Properties
6.2 Conductor
6.2.1 Metal Conductor
6.2.2 Transparent Conducting Oxide (TCO)
6.3 Semiconductor
6.3.1 Inorganic Semiconductor
6.3.2 Organic Semiconductor
6.3.3 Application of Semiconductor
6.4 Superconductor
6.4.1 Phenomenon and Definition
6.4.2 Meissner Effect
6.4.3 Critical Magnetic FieId
6.4.4 Critical Current Density (Jc)
6.4.5 Thermal Dynamic Features
6.4.6 Classification of Superconductor
6.4.7 Theory about Superconducting
6.4.8 Tunnelling/Josephson Effect
6.4.9 Applications of Superconductor
6.5 Dielectric Material
6.5.1 What is Dielectric Material
6.5.2 Characterization
6.5.3 Polarization Mechanism
6.5.4 Complex Dielectric Constant and Dielectric Loss
6.5.5 Dielectric Breakdown
6.6 Thermoelectricity of Material
6.6.1 Thermoelectric Potential and Absolute Thermoelectric Coefficient
6.6.2 Classification
6.6.3 Applications
Vocabulary
Problems
Chapter 7 Magnetic Properties
7.1 Introduction
7.2 Characterization and Principles for Magnetism
7.2.1 Magnetic Field Intensity and Magnetic Force-- Macroscopic Approach
7.2.2 Magnetic Dipole, Magnetic Moment and Magnetization-- Microscopic Approach
7.2.3 Magnetic Inductance, Permeability and Magnetic Susceptibility
7.2.4 Magnetism Classification
7.3 Features of Ferromagnetic Materials
7.3.1 Curie Point
7.3.2 Order-Disorder Transformations
7.3.3 Magnetic Domain
7.3.4 Features of Ferromagnetic Materials in Magnetic Fields
7.4 Functional Magnetic Materials
Vocabulary
Problems
Chapter 8 Optical Properties
8.1 Light
8.1.1 History of Optical Science
8.1.2 Light Wave-Electromagnetic Wave
8.2 Interaction of Light with Materials
8.2.1 Macro Phenomena
8.2.2 Mechanisms
8.3 Optical Property of Materials
8.3.1 Metals
8.3.2 Nonmetals
8.4 Applications of Optical Materials
8.4.1 Optical Fibers in Communications
8.4.2 Plastic Optics
8.4.3 Luminescent Materials (Inorganic Only)
Vocabulary
Problems
Chapter 9 Thermal Properties
9.1 Heat Capacity
9.1.1 Definition
9.1.2 Classical Model (Dulong-Petit Law)
9.1.3 Einstein Model
9.1.4 Debye Model
9.1.5 Comparison of Models
9.1.6 Heat Capacity in Real Materials
9.2 Thermal Conductivity
9.2.1 Thermal Conductivity and Thermal Diffusivity
9.2.2 Mechanism for Heat Conduction
9.2.3 Thermal Conduction in Real Materials
9.3 Thermal Expansion
9.3.1 Length and Volume Thermal Expansions
9.3.2 Theory for Thermal Expansion
9.3.3 Thermal Expansion and Heat Capacity
9.3.4 Thermal Expansion and Melting Point
9.4 Thermal Stability and Thermal Shock
Vocabulary
Problems
参考文献

密保秀1.编写《有机电子学》获得了校级精品教材的立项、江苏省精品教材的立项、“中华优秀出版物奖图书提名奖”。2.2008年，获得***新世纪优秀人才支持计划，2009年，获得南京邮电大学校长特聘教授称号，2010年入选博士研究生导师。获授权美国发明专利4项，授权/公开中国发明专利12项。文章被多次引用（累计引用次数1000余次）。3.2015年获校级微课比赛3等奖、校级名师荣誉称号。

1.填补我国材料物理双语教材的空白。
2.独特的内容结构，有别于传统《材料物理》主要针对金属及非金属中的无机材料，本书加入有机材料的物理特性。
3.教学名师双语编排，文章均来自原汁原味的英文参考书，提供准确、深入浅出。

全书内容包括：（1）材料的组织结构的基本知识（晶体结构及缺陷）；（2）材料的性质，主要侧重材料的电学性质（包括传导理论，影响材料电学性质的因素，材料的应用）、光学性质（光与物质的相互作用，应用等），及其光电特性（光生电，电生光的原理及应用），介绍材料结构与这些性质的关系和影响。为了教材内容的完整，在材料的性质部分，我们也简要地撰写了材料的力学及热学性质。

1.填补我国材料物理双语教材的空白。2.独特的内容结构，有别于传统《材料物理》主要针对金属及非金属中的无机材料，本书加入有机材料的物理特性。3.教学名师双语编排，文章均来自原汁原味的英文参考书，提供准确、深入浅出。