Overview

For courses in semiconductor devices.   Prepare your students for the semiconductor device technologies of today and tomorrow.   Modern Semiconductor Devices for Integrated Circuits, First Edition introduces students to the world of modern semiconductor devices with an emphasis on integrated circuit applications. Written by an experienced teacher, researcher, and expert in industry practices, this succinct and forward-looking text is appropriate for both undergraduate and graduate students, and serves as a suitable reference text for practicing engineers. 

Full Product Details

Author:   Chenming Hu ,  Chenming Hu
Publisher:   Pearson Education (US)
Imprint:   Pearson
Edition:   United States ed
Dimensions:   Width: 17.80cm , Height: 2.00cm , Length: 23.40cm
Weight:   0.680kg
ISBN:  

9780136085256

ISBN 10:   0136085253
Pages:   384
Publication Date:   24 August 2009
Audience:   College/higher education ,  Tertiary & Higher Education
Replaced By:   9780137006687
Format:   Hardback
Publisher's Status:   Active
Availability:   In Print  
This item will be ordered in for you from one of our suppliers. Upon receipt, we will promptly dispatch it out to you. For in store availability, please contact us.

Table of Contents

 1 Electrons and Holes in Semiconductors 1 1.1 Silicon Crystal Structure 1 1.2 Bond Model of Electrons and Holes 4 1.3 Energy Band Model 8 1.4 Semiconductors, Insulators, and Conductors 11 1.5 Electrons and Holes 12 1.6 Density of States 15 1.7 Thermal Equilibrium and the Fermi Function 16 1.8 Electron and Hole Concentrations 19 1.9 General Theory of n and p 25 1.10 Carrier Concentrations at Extremely High and Low Temperatures 28 1.11 Chapter Summary 29 PROBLEMS 30 REFERENCES 33 GENERAL REFERENCES 34  2 Motion and Recombination of Electrons and Holes 35 2.1 Thermal Motion 35 2.2 Drift 38 2.3 Diffusion Current 46 2.4 Relation Between the Energy Diagram and V, _ 47 2.5 Einstein Relationship Between D and μ 48 2.6 Electron—Hole Recombination 50 2.7 Thermal Generation 52 2.8 Quasi-Equilibrium and Quasi-Fermi Levels 52 2.9 Chapter Summary 54 PROBLEMS 56 REFERENCES 58 GENERAL REFERENCES 58 3 Device Fabrication Technology 59 3.1 Introduction to Device Fabrication 60 3.2 Oxidation of Silicon 61 3.3 Lithography 64 3.4 Pattern Transfer–Etching 68 3.5 Doping 70 3.6 Dopant Diffusion 73 3.7 Thin-Film Deposition 75 3.8 Interconnect–The Back-End Process 80 3.9 Testing, Assembly, and Qualification 82 3.10 Chapter Summary–A Device Fabrication Example 83 PROBLEMS 85 REFERENCES 87 GENERAL REFERENCES 88  4 PN and Metal—Semiconductor Junctions 89 Part I: PN Junction 89 4.1 Building Blocks of the PN Junction Theory 90 4.2 Depletion-Layer Model 94 4.3 Reverse-Biased PN Junction 97 4.4 Capacitance-Voltage Characteristics 98 4.5 Junction Breakdown 100 4.6 Carrier Injection Under Forward Bias–Quasi-Equilibrium Boundary Condition 105 4.7 Current Continuity Equation 107 4.8 Excess Carriers in Forward-Biased PN Junction 109 4.9 PN Diode IV Characteristics 112 4.10 Charge Storage 115 4.11 Small-Signal Model of the Diode 116 Part II: Application to Optoelectronic Devices 117 4.12 Solar Cells 117 4.13 Light-Emitting Diodes and Solid-State Lighting 124 4.14 Diode Lasers 128 4.15 Photodiodes 133 Part III: Metal—Semiconductor Junction 133 4.16 Schottky Barriers 133 4.17 Thermionic Emission Theory 137 4.18 Schottky Diodes 138 4.19 Applications of Schottky Diodes 140 4.20 Quantum Mechanical Tunneling 141 4.21 Ohmic Contacts 142 4.22 Chapter Summary 145 PROBLEMS 148 REFERENCES 156 GENERAL REFERENCES 156 5 MOS Capacitor 157 5.1 Flat-Band Condition and Flat-Band Voltage 158 5.2 Surface Accumulation 160 5.3 Surface Depletion 161 5.4 Threshold Condition and Threshold Voltage 162 5.5 Strong Inversion Beyond Threshold 164 5.6 MOS C—V Characteristics 168 5.7 Oxide Charge–A Modification to Vfb and Vt 172 5.8 Poly-Si Gate Depletion–Effective Increase in Tox 174 5.9 Inversion and Accumulation Charge-Layer Thicknesses –Quantum Mechanical Effect 176 5.10 CCD Imager and CMOS Imager 179 5.11 Chapter Summary 184 PROBLEMS 186 REFERENCES 193 GENERAL REFERENCES 193 6 MOS Transistor 195 6.1 Introduction to the MOSFET 195 6.2 Complementary MOS (CMOS) Technology 198 6.3 Surface Mobilities and High-Mobility FETs 200 6.4 MOSFET Vt, Body Effect, and Steep Retrograde Doping 207 6.5 QINV in MOSFET 209 6.6 Basic MOSFET IV Model 210 6.7 CMOS Inverter–A Circuit Example 214 6.8 Velocity Saturation 219 6.9 MOSFET IV Model with Velocity Saturation 220 6.10 Parasitic Source-Drain Resistance 225 6.11 Extraction of the Series Resistance and the Effective Channel Length 226 6.12 Velocity Overshoot and Source Velocity Limit 228 6.13 Output Conductance 229 6.14 High-Frequency Performance 230 6.15 MOSFET Noises 232 6.16 SRAM, DRAM, Nonvolatile (Flash) Memory Devices 238 6.17 Chapter Summary 245 PROBLEMS 247 REFERENCES 256 GENERAL REFERENCES 257  7 MOSFETs in ICs–Scaling, Leakage, and Other Topics 259 7.1 Technology Scaling–For Cost, Speed, and Power Consumption 259 7.2 Subthreshold Current–“Off” Is Not Totally “Off” 263 7.3 Vt Roll-Off–Short-Channel MOSFETs Leak More 266 7.4 Reducing Gate-Insulator Electrical Thickness and Tunneling Leakage 270 7.5 How to Reduce Wdep 272 7.6 Shallow Junction and Metal Source/Drain MOSFET 274 7.7 Trade-Off Between Ion and Ioff and Design for Manufacturing 276 7.8 Ultra-Thin-Body SOI and Multigate MOSFETs 277 7.9 Output Conductance 282 7.10 Device and Process Simulation 283 7.11 MOSFET Compact Model for Circuit Simulation 284 7.12 Chapter Summary 285 PROBLEMS 286 REFERENCES 288 GENERAL REFERENCES 289 8 Bipolar Transistor 291 8.1 Introduction to the BJT 291 8.2 Collector Current 293 8.3 Base Current 297 8.4 Current Gain 298 8.5 Base-Width Modulation by Collector Voltage 302 8.6 Ebers—Moll Model 304 8.7 Transit Time and Charge Storage 306 8.8 Small-Signal Model 310 8.9 Cutoff Frequency 312 8.10 Charge Control Model 314 8.11 Model for Large-Signal Circuit Simulation 316 8.12 Chapter Summary 318 PROBLEMS 319 REFERENCES 323 GENERAL REFERENCES 323 Appendix I Derivation of the Density of States 325 Appendix II Derivation of the Fermi—Dirac Distribution Function 329 Appendix III Self-Consistencies of Minority Carrier Assumptions 333 Answers to Selected Problems 337 Index 341

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Author Information

Chenming Calvin Hu holds the TSMC Distinguished Professor Chair of Microelectronics at University of California, Berkeley.  He is a member of the US Academy of Engineering and a foreign member of the Chinese Academy of Sciences. From 2001 to 2004, he was the Chief Technology Officer of TSMC. A Fellow of the Institute of Electrical and Electronic Engineers (IEEE), he has been honored with the Jack Morton Award in1997 for his research on transistor reliability, the Solid State Circuits Award in 2002 for co-developing the first international standard transistor model for circuit simulation, and the Jun-ichi Nishizawa Medal in 2009 for exceptional contributions to device physics and scaling. He has supervised over 60 Ph.D. student theses, published 800 technical articles, and received more than 100 US patents. His other honors include Sigma Xi Moni Ferst Award, R&D 100 Award, and UC Berkeley’s highest award for teaching — the Berkeley Distinguished Teaching Award. For additional information, visit the author's Web site.

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