半導體多層膜中的電子和聲子（第二版）（英文影印版）

納米技術的發展催生了只有幾個分子厚度的半導體結構，這給該結構中電子和聲子的物理帶來了重要影響。本書闡述了量子阱和量子線中的電子和聲子囚禁對半導體特性的影響。第二版中加入了電子自旋弛豫、六角纖鋅晶格、氮化物結構和太赫茲源等方面的內容。本書獨特之處在於對光學聲子的微觀理論的闡述，其由囚禁引起的徑向性質改變以及與電子的相互作用等。 本書適合半導體物理領域的研究者和研究生閱讀。

本書是影印版英文專著，原書由劍橋大學出版社於2009年出版。半導體科學與技術是當代最重要的研究領域。因之催生的各種套用數不勝數。半導體多層膜則是納米技術發展的產物，具有重要的科研價值和巨大的套用潛力。本書作為研究其中電子和聲子的學術專著，一定會給這一領域的研究者以很大的收穫。

Preface page xi

Introduction 1

1 Simple Models of the Electron-Phonon Interaction 9

1.1 General Remarks 9

1.2 Early Models of Optical-Phonon Confinement 10

1.3 The Interaction of Electrons with Bulk Phonons 22

1.4 The Interaction with Model Confined Phonons 35

2 Quantum Confinement of Carriers 42

2.1 The Effective-Mass Equation 42

2.2 The Confinement of Electrons 49

2.3 The Confinement of Holes 53

2.4 Angular Dependence of Matrix Elements 62

2.5 Non-Parabolicity 64

2.6 Band-Mixing 66

3 Quasi-Continuum Theory of Lattice Vibrations 67

3.1 Introduction 67

3.2 Linear-Chain Models 69

3.3 The Envelope Function 76

3.4 Non-Local Operators 78

3.5 Acoustic and Optical Modes 80

3.6 Boundary Conditions 83

3.7 Interface Model 85

3.8 Summary 91

Appendix: The Local Approximation 94

4 Bulk Vibrational Modes in an Isotropic Continuum 97

4.1 Elasticity Theory 97

4.2 Polar Material 104

4.3 Polar Optical Waves 105

4.4 Energy Density 107

4.5 Two-Mode Alloys 114

5 Optical Modes in a Quantum Well 119

5.1 Non-Polar Material 119

5.2 Polar Material 122

5.3 Barrier Modes: Optical-Phonon Tunnelling 127

5.4 The Effect of Dispersion 137

5.5 Quantization of Hybrid Modes 137

6 Superlattice Modes 141

6.1 Superlattice Hybrids 141

6.2 Superlattice Dispersion 144

6.3 General Features 148

6.4 Interface Polaritons in a Superlattice 154

6.5 The Role of LO and TO Dispersion 155

6.6 Acoustic Phonons 157

7 Optical Modes in Various Structures 160

7.1 Introduction 160

7.2 Monolayers 160

7.3 Metal-Semiconductor Structures 170

7.4 Slab Modes 173

7.5 Quantum Wires 176

7.6 Quantum Dots 181

8 Electron-Optical Phonon Interaction in a Quantum Well 182

8.1 Introduction 182

8.2 Scattering Rate 183

8.3 Scattering Potentials for Hybrids 184

8.4 Matrix Elements for an Indefinitely Deep Well 185

8.5 Scattering Rates for Hybrids 187

8.6 Threshold Rates 189

8.7 Scattering by Barrier LO Modes 192

8.8 Scattering by Interface Polaritons 194

8.9 Summary of Threshold Rates in an Indefinitely Deep Well 197

8.10 Comparison with Simple Models 199

8.11 The Interaction in a Superlattice 202

8.12 The Interaction in an Alloy 205

8.13 Phonon Resonances 206

8.14 Quantum Wire 208

8.15 The Sum-Rule 209

Appendix: Scalar and Vector Potentials 212

9 Other Scattering Mechanisms 217

9.1 Charged-Impurity Scattering 217

9.2 Interface-Roughness Scattering 227

9.3 Alloy Scattering 230

9.4 Electron-Electron Scattering 231

9.5 Phonon Scattering 236

10 Quantum Screening 244

10.1 Introduction 244

10.2 The Density Matrix 245

10.3 The Dielectric Function 248

10.4 The 3D Dielectric Function 250

10.5 The Quasi-2D Dielectric Function 252

10.6 The Quasi-1D Dielectric Function 259

10.7 Lattice Screening 265

10.8 Image Charges 266

10.9 The Electron-Plasma/Coupled-Mode Interaction 268

10.10 Discussion 272

11 The Electron Distribution Function 275

11.1 The Boltzmann Equation 275

11.2 Net Scattering Rate by Bulk Polar-Optical Phonons 276

11.3 Optical Excitation 278

11.4 Transport 281 1

11.5 Acoustic-Phonon Scattering 290

11.6 Discussion 296

11.7 Acoustic-Phonon Scattering in a Degenerate Gas 300

12 Spin Relaxation 311

12.1 Introduction 311

12.2 The Elliot-Yafet process 313

12.3 The D'yakonov-Perel Process 317 1

12.4 The Rashba Mechanism 326

12.5 The Bir-Aranov-Pikus Mechanism 326

12.6 Hyperfine Coupling 329

Appendix 1 332 Appendix 2 333 Appendix 3 335

13 Electrons and Phonons in the Wurtzite Lattice 336

13.1 The Wurtzite Lattice 336

13.2 Energy Band Structure 338

13.3 Eigenfunctions 340

13.4 Optical Phonons 343

13.5 Spontaneous Polarization 346

Appendix 1 Symmetry 347

14 Nitride Heterostructures 349

14.1 Single Heterostructures 349

14.2 Piezoelectric Polarization 351

14.3 Polarization Model of Passivated HFET with Field Plate 354

14.4 The Polarization Superlattice 358

14.5 The AlN/GaN Superlattice 360

14.6 The Quantum-Cascade Laser 366

Appendix Airy Functions 368

15 Terahertz Sources 369

15.1 Introduction 369

15.2 Bloch Oscillations 370

15.3 Negative-Mass NDR 373

15.4 Ballistic Transport 378

15.5 Femtosecond Generators 387

15.6 CW Generators 389

Appendix 392

Appendix 1 The Polar-Optical Momentum-Relaxation Time in a 2D Degenerate Gas 393

Appendix 2 Electron/Polar Optical Phonon Scattering Rates in a Spherical Cosine Band 395

References 397

Index 406