固态电子器件

内容概要

Ben G.Streetman是美国国家工程院院士和美国艺术与科学院院士，IEEE会士和美国电化学学会（ECS）会士。现任美国得克萨斯大学奥斯汀分校工学院院长和该鹇电机工程与计算机工程讲座教授，也是该校微电子研究中心的创始人和第一任主任（1984年-1996年）。Streetman教授的教

书籍目录

1 CRYSTAL PROPERTIES AND GROWTH OF SEMICONDUCTORS       1.1 Semiconductor Materials     1.2 Crystal Lattices       1.2.1  Periodic Structures       1.2.2  Cubic Lattices       1.2.3  Planes and Directions       1.2.4  The Diamond Lattice     1.3  BulkCrystalGrowth       1.3.1  Starting Materials       1.3.2  Growth of Single-Crystal Ingots       1.3.3  Wafers       1.3.4  Doping     1.4  Epitaxial Growth       1.4.1  Lattice-Matching in Epitaxial Growth       1.4.2  Vapor-Phase Epitaxy       1.4.3  Molecular Beam Epitaxy 2 ATOMS AND ELECTRONS     2.1  Introduction to Physical Models     2.2  Experimental Observations       2.2.1  The Photoelectric Effect          Atom i Spectra     2.3  The Bohr Modlel    2.4  Quantum Mechanics       2.4.1  Probability and the Uncertainty Principle       2.4.2  The Schr6dinger Wave Equation       2.4.3  PotentialWellProblem       2.4.4  Tunneling     2.5  Atomic Structure and the Periodic lable       2.5.1  The Hydrogen Atom       2.5.2  The Periodic Table  3  ENERGY BANDS AND CHARGE CARRIERS IN SEMICONDUCTORS     3.1  Bonding Forces and Energy Bands in Solids       3.1.1  Bonding Forces in Solids       3.1.2  Energy Bands       3.1.3  Metals, Semiconductors, and Insulators       3.1.4  Direct and Indirect Semiconductors       3.1.5 Variation o! Energy Bands with AIIo Composition    3.2  Charge Carriers Semiconductors     3.2.1  Electrons and Holes       3.2.2  Effective Mass       3.2.3  Intrinsic Material       3.2.4  Extrinsic Material       3.2.5  Electrons and Holes in Quantum Wells     3.3  Carrier Concentrations       3.3.1  TheFermiLevel       3.3.2  Electron and Hole Concentrations at Equilibrium       3.3.3  Temperature Dependence of Carrier Concentrations       3.3.4  Compensation and Space Charge Neutrality     3.4  Drift of Carriers in Electric and Magnetic Fields       3.4.1  Conductivity and Mobility'       3.4.2  Drift and Resistance       3.4.3  Effects of lemperature and Doping on Mobility'      3.4.4  High-Field Effects      3.4 5  The Hall Effect    3.5  Invariance of the Fermi Level at Equilibrium          EXCESS CARRIERS IN SEMICONDUCTORS    4.1  Optical Absorption     4.2  Luminescence       4.2.1  Photoluminescence      4.2.2  Electroluminescence    4.3  Carrier Lifetime and Photoconductivity      4.3.1  Direct Recombination of Electrons and Holes      4.3.2  Indirect Recombination; Trapping       4.3.3  Steady State Carrier Generation; Quasi-Fermi Levels      4.3 4  Photoconductive Devices     4.4  Diffusion of Carriers       4.4.1  Diffusion Processes       4.4.2  Diffusion and Drift of Carriers; Built-in Fields      4.4.3  Diffusion and Recombination; The Continuity Equation       4.4.4  Steady State Carrier Injection; Diffusion Length       4.4.5  The Haynes-Shockley Experiment       4.4.6  Gradients in the Quasi-Fermi Levels  5 JUNCTIONS      5.1  Fabrication of p-n Junctions      5.1.1  Thermal Oxidation       5.1.2  Diffusion       5.1.3  Rapid Thermal Processing       5.1.4  Ion Implantation       5.1.5  Chemical Vapor Deposition (CVD)       5.1.6  Photolithography       5.1.7  Etching       5.1.8  Metallization     5.2  Equilibrium Conditions       5.2.1  The Contact Potential       5.2.2  Equilibrium Fermi Levels       5.2.3  Space Charge at a Junction     5.3  Forward-and Reverse-Biased Junctions;Steady State Conditions       5.3.1  Qualitative Description of Current Flow at a Junction     5.3.2  Carrier Injection       5.3.3  Reverse Bias    5.4  Reverse-Bias Breakdown       5.4.1  Zener Breakdown       5.4.2  Avalanche Breakdown       5.4.3  Rectifiers       5.4.4  The Breakdown Diode     5.5  Transient and A-C Conditions       5.5.1  Time Variation of Stored Charge       5.5.2  Reverse Recovery Transient       5.5.3  Switching Diodes      5.5.4  Capacitance of p-n junctions      5.5.5  The Varactor Diode    5.6  Deviations from the Simpl Theory       5.6.1  Effects of Contact Potential on Carrier Injection      5.6.2  Recombination and Generation in the Transition Region      5.6.3  Ohmic Losses     5.6.4  Graded Junctions     5.7  Metal-Semiconductor Junctions       5.7.1  Schottky Barriers       5.7.2  Rectifying Contacts       5.7.3  Ohmic Contacts       5.7.4  lypical Schottky Barriers     5.8  Heterojunctions  6 FIELD-EFFECT TRANSISTORS     6.1  Transistor Operation       6.1.1  The Load Line       6.1.2 Amplification a4d Switching   6.2  The Junction FET       6.2.1  Pinch-off and Saturation       6.2.2  Gate Control       6.2.3 Current-VoltageCharacteristics    6.3  The MetaI-SemiconductorFET       6.3.1  The GaAs MESFET       6.3.2  The High Electron Mobility Transistor (HEMT)       6.3.3  Short Channel Effects     6.4  The Metal-Insulator-Semiconductor FET       6.4.1  Basic Operation and Fabrication       6.4.2  The Ideal MOS Capacitor       6.4.3  Effects of Real Surfaces       6.4.4  ThresholdVoltage       6.4.5  MOS Capacitance-Voltage Analysis       6.4.6  Time-Dependent Capacitance Measurements       6.4.7 Current-Voltage Characteristics of MOS Gate Oxides    6.5  The MOSField-EffectTrans~stor      6.5.1  Output Characteristics       6.5.2  Transfer Characteristics       6.5.3  Mobility Models     6.5.4  Short Channel MOSFET I-V Characteristics       6.5.5  Control of Threshold Voltage       6.5.6  Substrate Bias Effects       6.5.7  Subthreshold Characteristics       6.5.8  Equivalent Circuit for the MOSFET       6.5.9  MOSFET Scaling and Hot Electron Effects       6.5.10 Drain-induced Barrier Lowering       6.5.11 Short Channel Effect and Narrow Width Effect       6.5.12 Gate-Induced Drain Leakage 7 BIPOLAR JUNCTION TRANSISTORS    7.1  Fundamentals o! BJT Operation     7.2  Amplification with BJTs     7.3  BJTFabrication     7.4  Minority Carrier Distributions and Terminal Currents       7.4.1  Solution of the Diffusion Equation in the Base Region       7.4.2  Evaluation of the Terminal Currents       7.4.3  Approximations of the Terminal Currents       7.4.4  Current Transfer Ratio     7.5  Generalized Biasing       7.5.1  The Coupled-Diode Model       7.5.2  Charge Control Analysis     7.6 Switching       7.6.1  Cutoff       7.6.2  Saturation       7.6.3  The Switching Cycle       7.6.4  Specifications for Switching Transistors     7.7 Other Important Effects       7.7.1  Drift in the Base Region       7.7.2  Base Narrowing       7.7.3  Avalanche Breakdown       7.7.4  Injection Level; Thermal Effects       7.7.5  Base Resistance and Emitter Crowding       7.7.6  GummeI-Poon Model       7.7 7  Kirk Effect     7.8  Frequency Limitations of Transistors       7.8.1  Capacitance and Charging Times       7.8.2  Transit Time Effects       7.8.3  Webster Effect       7.8.4  High-Frequency Transistors     7.9  Heterojunction  polar Transistors  8  OPTOELECTRONIC DEVICES     8.1  Photodiodes       8.1.1  Current and Voltage in an Illuminated Junction       8.1.2  SolarCells       8.1.3  Photodetectors       8.1.4  Gain, Bandwidth, and Signal-to-Noise Ratio of Photodetectors     8.2  Light-Emitting Diodes      8.2.1  Light-Emitting Materials      8.2.2  Fiber-Optic Communications     8.3  Lasers     8.4  Semiconductor Lasers       8.4.1  Population Inversion at a Junction       8.4.2  Emission Spectra for p-n Junction Lasers       8.4.3  The Basic Semiconductor Laser       8.4.4  Heterojunction Lasers       8.4.5  Materials for Semiconductor Lasers  9 INTEGRATED CIRCUITS     9.1  Background       9.1.1  Advantages of Integration       9.1.2  Types of Integrated Circuits    9.2 Evolution oflntegrated Circuits    9.3 Monolithic Device Elements       9.3.1  CMOS Process Integration       9.3.2  Silicon-on-Insulator (SOl)       9.3.3  Integration of O.ther Circuit Elements     9.4    arge Transfer Devices       9.4.1  Dynamic Effects in MOS Capacitors       9.4.2  The Basic CCD       9.4.3  Improvements on the Basic Structure       9.4.4  App_lications of CCDs    9.5  Ultra LargeScalelntegration(ULSI)       9.5.1  Logic Devices       9.5.2  Semiconductor Memories     9.6  resting, Bonding, and Packaging       9.6.1  Testing       9.6.2  Wire Bonding       9.6.3  Flip-Chip Techniques       9.6.4  Packaging  1O HIGH-FREQuENCY AND HIGH-POWER DEVICES    10.1 Tunnel Diodes       10.1.1 Degenerate Semiconductors    10.2 The IMPATT Diode    10.3 The Gunn Diode       10.3.1 The Transferred-Electron Mechanism      10.3.2 Formation and Drift of Space Charge Domains     10.4 The p-n-p-n Diode      10.4.1 Basic Structure       10.4.2 The Two-Transistor Analogy      10.4.3 Variation of α with Injection      10.4.4 Forward-Blocking State       10.4.5 ConductingState  524     10.4.6 Triggering Mechanisms    10.5 The Semiconductor-Controlle rectifier       10.5.1 Turning off the SCR     10.6 Insulated-Gate Bipolar Transistor  APPENDICES  Ⅰ. Definitions of Commonly Used Symbols   Ⅱ. Physical Constants and Conversion Factors    Ⅲ. Properties of Semiconductor Materials    Ⅳ. Derivation of the Density of States in the Conduction Band    Ⅴ. Derivation of Fermi-Dirac Statistics    Ⅵ. Dry and Wet Thermal Oxide Thickness Grown on      Si(100) as a Function of Time and. lemperature    Ⅶ. Solid Solubilities of Impurities in    Ⅶ. Diffusivities of Dopants in Si and SiO2   Ⅸ. Projected Range and Straggle as Function of      Implant Energy in Si  ANSWERS TO SELECTED SELF QUIZ QUESTIONS INDEX

作者简介

本书是介绍半导体器件工作原理的经典入门教材，其主要内容包括固体物理基础和半导体器件物理两大部分，同时也涵盖半导体晶体结构与材料生长技术、集成电路原理与制造工艺以及光电子器件与高频大功率器件等相关内容。

　　本书注重基本物理概念，强调理论联系实际，可作为高等院校电子信息类专业“固态器件与电路”专业基础课的教材，也可供相关领域的研究人员和技术人员参考。

图书封面

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