纳米材料物理基础
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作者张邦维
出版社化学工业出版社
ISBN9787122329455
出版时间2019-01
装帧精装
开本16开
定价298元
货号1201800180
上书时间2024-09-03
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目录
Foreword xi
Preface xiii
Translator’s Preface xv
Preface to the English Version of “Physical Fundamentals of Nanomaterials” xvii
Acknowledgment and Authorization Details for Figures Used in the Book xix
CHAPTER 1 Introduction 1
1.1 Nanomaterial Age 1
1.2 What Are Nanomaterials? 3
1.3 History of Nanomaterial Development 5
1.3.1 Germination Stage 5
1.3.2 Preliminary Preparation Stage 7
1.3.3 Rapid-Development Stage 8
1.3.4 Industrial and Commer Application Stage 10
1.4 Importance of Nanomaterials 11
1.4.1 Nanotechnology Programs of Leading Countries 11
1.4.2 Nanotechnology Investment Among Leading Countries 11
1.4.3 Analysis of the Importance of Nanotechnology 13
1.5 Potential Problems of Nanomaterials 14
1.6 Purpose of This Book: Fundamentals of Nanomaterial Physics 17
References 18
CHAPTER 2 Principles, Methods, Formation Mechanisms, and Structures of Nanomaterials Prepared via Gas-Phase Processes 19
2.1 Principles of Physical Vapor Deposition 20
2.1.1 Nucleation 21
2.1.2 Growth 22
2.2 Physical Vapor Deposition 26
2.2.1 Electrical Resistance Heating Method 26
2.2.2 Plasma Heating Method 29
2.2.3 Laser Heating Method 31
2.3 Chemical Vapor Deposition 38
2.3.1 CVD Thermodynamics and Kinetics 39
2.3.2 CVD Process Technology for Nanomaterial Preparation 42
2.3.3 Catalytic CVD and CNT Preparation 48
2.4 Filtered Cathodic Vacuum Arc Deposition 58
2.4.1 Magnetic Filtration and FCVA Devices 59
2.4.2 Examples of Filtered Cathodic Vacuum Deposition Films 60
2.5 Comparison of Various Vapor Deposition Methods 65
References 66
CHAPTER 3 Principles, Methods, Formation Mechanisms, and Structures of Nanomaterials Prepared in the Liquid Phase 71
3.1 Precipitation 72
3.1.1 Coprecipitation and Fractional Precipitation 72
3.1.2 Homogeneous Precipitation 75
3.2 Sol-Gel Method 82
3.2.1 Sol-Gel Procedure 83
3.2.2 Sol-Gel Reaction Mechanism 83
3.2.3 Examples of Sol-Gel Prepared Nanomaterials 84
3.3 Chemical-Reduction Method 94
3.3.1 Chemical-Reduction Preparation Technology 94
3.3.2 Chemical-Reduction Reaction Mechanisms 102
3.3.3 Preparation of Crystalline Nanomaterials via Chemical Reduction 103
3.4 Comparison of Various Liquid Nanoparticle Preparation Methods 108
References 109
CHAPTER 4 Principles, Methods, Formation Mechanisms, and Structures of Nanomaterials Prepared via Solid-Phase Syntheses 113
4.1 Mechanical Alloying 114
4.1.1 Ball Mill 115
4.1.2 MA Process Parameters 116
4.1.3 MA-Prepared Nanopowder Formation Mechanisms 120
4.1.4 Examples of Nanomaterials Synthesized via Mechanical Alloying 123
4.2 Nanomaterial Preparation via Solid-Phase Methods 127
4.2.1 Preparation of Bulk Nanomaterials via Solid-Phase Methods 128
4.2.2 Amorphous Nanocrystallization 139
4.3 Microstructures and Defects in Body Nanomaterials 153
4.3.1 Grains in Body Nanomaterials 153
4.3.2 Grain Boundaries in Body Nanomaterials 157
4.3.3 Defects in Body Nanomaterials 163
References 172
CHAPTER 5 Principles, Methods, Formation Mechanisms, and Structures of Nanomaterials Prepared via Self-Assembly 177
5.1 What Is Self-Assembly? 178
5.2 Types and Common Characteristics of Self-Assembly Mechanisms 179
5.2.1 Types of Self-Assembly Mechanisms 179
5.2.2 Common Characteristics of Self-Assembly 182
5.3 Nanomaterial Fabrication via Self-Assembly 183
5.3.1 Metal and Alloy Components 183
5.3.2 Semiconductor Components 187
5.3.3 Polymer Supermolecules and Biomolecular Components 192
5.4 Template-Based Nanomaterial Fabrication 202
5.4.1 Fabrication of Ordered Nanohole Templates 202
5.4.2 Metal and Alloy Nanomaterials Prepared via Templated Self-Assembly 204
5.4.3 Preparation of Semiconductor Nanomaterials via Self-Assembly 206
References 209
CHAPTER 6 Mechanical Properties of Nanomaterials 211
6.1 Elasticity of Nanomaterials 212
6.2 Strengths, Hardnesses and HallPetch Relationships in Nanomaterials 216
6.2.1 Experimental Strength Data 217
6.2.2 The Relationship Between Hardness and HallPetch Effects 222
6.3 Nanomaterial Fracture and Fatigue 223
6.3.1 Facture Strength and Toughness 224
6.3.2 Fatigue 226
6.4 Nanomaterial Creep and Superplasticity 229
6.4.1 Creep 230
6.4.2 Superplasticity 237
6.5 Deformation and Fracture Mechanisms in Nanomaterials 242
6.5.1 Nanomaterial Deformation Mechanisms 243
6.5.2 Nanomaterial Fracture Mechanisms 245
References 248
CHAPTER 7 Thermal Properties of Nanomaterials 251
7.1 Melting Point 252
7.1.1 Elevated and Lowered Nanomaterial Melting Points 252
7.1.2 Nanomaterial Melting Point Simulations 253
7.1.3 Melting Enthalpy and Entropy in Nanomaterials 258
7.1.4 Nanoalloy Phase Diagrams 259
7.2 Thermal Conductivity 261
7.2.1 Experimental Measurement of Nanomaterial Thermal Conductivities 261
7.2.2 Theoretical Simulation of Nanomaterial Thermal Conductivity 268
7.3 Specific Heat 270
7.3.1 Debye Temperatures of Nanomaterials 270
7.3.2 Specific Heats of Nanomaterials 276
7.4 Thermal Expansion 281
References 287
CHAPTER 8 Optical Properties of Nanomaterials 291
8.1 Light Absorption of Nanomaterials 292
8.1.1 Instances of Light Absorption Nanomaterials 292
8.1.2 Red- and Blueshift Phenomenon of Light Absorption 294
8.2 Colors of Nanomaterials 298
8.3 Light-Emission of Nanomaterials 301
8.3.1 Quantum Yield 302
8.3.2 Photoluminescence of Nanomaterials 305
8.3.3 Electroluminescence of Nanomaterials 311
8.4 Magnetooptical Properties of Nanomaterials 319
8.4.1 Magnetooptical Effect 319
8.4.2 Magnetooptical Effect of Metal Nanoparticles and Nanoparticle Films 322
8.4.3 Magnetooptical Effect of Oxide Nanoparticles 328
8.4.4 Magnetooptical Effect of Composite Structure of Amorphous Magnetic Nanoparticles 331
References 333
CHAPTER 9 Electrical Properties of Nanometer Materials 337
9.1 Resistivity of Nanomaterials 338
9.1.1 Resistivity of Metal Nanomaterials 338
9.1.2 Resistivity of Alloy Nanomaterials 345
9.1.3 Resistivity of Semiconductor Nanomaterials 347
9.1.4 Resistivity of Oxide Nanomaterials 349
9.2 Theoretical Simulation of Resistivity for Nanomaterials 352
9.2.1 FS and MS Resistivity Theory 352
9.2.2 Theoretical Calculation of Resistivity of Metal Nanowires 353
9.2.3 Empirical Formula for Nanomaterial Resistivity 355
9.3 Thermoelectric Conversion Efficiency of Nanomaterials 356
9.3.1 Thermoelectric Conversion Efficiency and Related Parameters 356
9.3.2 Thermoelectric Conversion Efficiency of Nanomaterials 360
9.3.3 Theoretical Calculations of Conversion Efficiency for Nanothermoelectric Materials 363
9.4 Superconductivity of Nanomaterials 366
9.4.1 Superconductivity of Nanoparticle 366
9.4.2 Superconductivity of Nanofilms 367
9.4.3 Nanowire Superconductivity 373
References 382
CHAPTER 10 Magnetic Properties of Nanomaterials 387
10.1 Magnetic Moment of Nanometer Magnetic Materials 388
10.1.1 Magnetic Moment of 3D Atomic Group Ferromagnetic Metals 388
10.1.2 Magnetic Moment of 3D Ferromagnetic Clusters of Superlattice 392
10.1.3 Magnetic Moments of Nonferromagnetic Three Metal Clusters 396
10.2 Curie Temperature of Nanomagnetic Materials 398
10.2.1 Reduction of Curie Temperature 398
10.2.2 Curie Temperature of Superlattice 402
10.3 Magnetization and Coercivity of Nanometer Magnetic Materials 406
10.3.1 Magnetization 406
10.3.2 Coercivity 413
10.4 Magnetoresistance and Giant Magnetoresistance of Nanometer Magnetic Materials 423
10.4.1 Magnetoresistance and Anisotropic Magnetoresistance 423
10.4.2 Magnetoresistance of Nanometer Manganese Perovskite 426
10.4.3 Giant Magnetoresistance 436
References 446
Index 451
内容摘要
本书以很新原始论文为素材,采取从读者出发的角度和态度,将纳米材料学发展现状和水平呈献给广大读者。着浓墨于纳米材料很主要和通常使用的制备方法、纳米材料的结构、它的形成机理、特别是 纳米材料物理性能理论的内容,而且包括了纳米材料的力学、热学、光学、电学、磁学等物理学性能方 面的内容。书中独特地强调了纳米材料的双刃性。
本书没有像其他纳米材料类书籍一样按照纳米材料的种类来编写,而是在作者总结和归纳的基础上 将其共性问题抽提出来进行阐述和讨论,使读者纳米材料的物理基础理论研究进展有了更深入地了解。
本书不仅能够给从事纳米材料研究的科研、技术人员以参考,而且能够拓宽相关专业高年级本科生和研究生的学术视野。
主编推荐
1.本书编排方式新颖。在作者总结和归纳的基础上将其共性问题抽提出来进行阐述和讨论,使读者对纳米材料的物理基础理论研究进展有了更深入的了解,对现今纳米材料的发展和现状有一个较明确、较全面的认识,同时能够引发对于纳米材料的兴趣,给立志在纳米材料的未来发展中做出贡献的年轻朋友们起到指引和帮助作用。
2.侧重于纳米材料的物理基础,强调不仅要知道是什么,还要懂得为什么。侧重于如何提出和解决问题,说明可能的发展趋势以及作者的看法和评论。
3.简短而很好醒目地指出纳米材料的毒性和对于人类与环境可能的危害。引起人们特别是公众对于纳米材料可能危害性的认识和防范,以毫不畏惧的态度正确面对。
4.本书并非全然的纳米材料的物理理论,书稿中公式不是很多,但作者对纳米材料的物理基础进行了严肃认真和深入浅出的描述,非专业人士也可以读懂。
5.按照气相、液相和固相,并把自组装抽出来单列的分类讨论体系。
6.书稿直接取材于约1300篇的原始科研文献资料,从而保证了书稿内容的优选性和科学性。同时也包括他们自己所发表的这些论文资料,使书稿更显得丰富多彩。
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