Nanotechnology for Microelectronics and Optoelectronics
Duart, J M Martinez
Nanotechnology for Microelectronics and Optoelectronics - New Delhi Elsevier 2006 - 279p.
Chapter 1: Mesoscopic Physics and Nanotechnologies
1.1 OUTLOOK OF THE BOOK
1.2 TRENDS IN NANOELECTRONICS AND OPTOELECTRONICS
1.3 CHARACTERISTIC LENGTHS IN MESOSCOPIC SYSTEMS
1.4 QUANTUM MECHANICAL COHERENCE
1.5 QUANTUM WELLS, WIRES, AND DOTS
1.6 DENSITY OF STATES AND DIMENSIONALITY
1.7 SEMICONDUCTOR HETEROSTRUCTURES
1.8 QUANTUM TRANSPORT
PROBLEMS
Chapter 2: Survey of Solid State Physics
2.1 INTRODUCTION
2.2 SHORT REVIEW OF QUANTUM MECHANICS
2.3 FREE ELECTRON MODEL OF A SOLID. DENSITY OF STATES FUNCTION
2.4 BLOCH THEOREM
2.5 ELECTRONS IN CRYSTALLINE SOLIDS
2.6 DYNAMICS OF ELECTRONS IN BANDS
2.7 LATTICE VIBRATIONS
2.8 PHONONS
PROBLEMS
Chapter 3: Review of Semiconductor Physics
3.1 INTRODUCTION
3.2 ENERGY BANDS IN TYPICAL SEMICONDUCTORS
3.3 INTRINSIC AND EXTRINSIC SEMICONDUCTORS
3.4 ELECTRON AND HOLE CONCENTRATIONS IN SEMICONDUCTORS
3.5 ELEMENTARY TRANSPORT IN SEMICONDUCTORS
3.6 DEGENERATE SEMICONDUCTORS
3.7 OPTICAL PROPERTIES OF SEMICONDUCTORS
PROBLEMS
Chapter 4: The Physics of Low-Dimensional Semiconductors
4.1 INTRODUCTION
4.2 BASIC PROPERTIES OF TWO-DIMENSIONAL SEMICONDUCTOR NANOSTRUCTURES
4.3 SQUARE QUANTUM WELL OF FINITE DEPTH
4.4 PARABOLIC AND TRIANGULAR QUANTUM WELLS
4.5 QUANTUM WIRES
4.6 QUANTUM DOTS
4.7 STRAINED LAYERS
4.8 EFFECT OF STRAIN ON VALENCE BANDS
4.9 BAND STRUCTURE IN QUANTUM WELLS
4.10 EXCITONIC EFFECTS IN QUANTUM WELLS
PROBLEMS
Chapter 5: Semiconductor Quantum Nanostructures and Superlattices
5.1 INTRODUCTION
5.2 MOSFET STRUCTURES
5.3 HETEROJUNCTIONS
5.4 QUANTUM WELLS
5.5 SUPERLATTICES
PROBLEMS
Chapter 6: Electric Field Transport in Nanostructures
6.1 INTRODUCTION
6.2 PARALLEL TRANSPORT
6.3 PERPENDICULAR TRANSPORT
6.4 QUANTUM TRANSPORT IN NANOSTRUCTURES
PROBLEMS
Chapter 7: Transport in Magnetic Fields and the Quantum Hall Effect
7.1 INTRODUCTION
7.2 EFFECT OF A MAGNETIC FIELD ON A CRYSTAL
7.3 LOW-DIMENSIONAL SYSTEMS IN MAGNETIC FIELDS
7.4 DENSITY OF STATES OF A 2D SYSTEM IN A MAGNETIC FIELD
7.5 THE AHARONOV–BOHM EFFECT
7.6 THE SHUBNIKOV–DE HAAS EFFECT
7.7 THE QUANTUM HALL EFFECT
PROBLEMS
Chapter 8: Optical and Electro-optical Processes in Quantum Heterostructures
8.1 INTRODUCTION
8.2 OPTICAL PROPERTIES OF QUANTUM WELLS AND SUPERLATTICES
8.3 OPTICAL PROPERTIES OF QUANTUM DOTS AND NANOCRYSTALS
8.4 ELECTRO-OPTICAL EFFECTS IN QUANTUM WELLS. QUANTUM CONFINED STARK EFFECT
8.5 ELECTRO-OPTICAL EFFECTS IN SUPERLATTICES. STARK LADDERS AND BLOCH OSCILLATIONS
PROBLEMS
Chapter 9: Electronic Devices Based on Nanostructures
9.1 INTRODUCTION
9.2 MODFETs
9.3 HETEROJUNCTION BIPOLAR TRANSISTORS
9.4 RESONANT TUNNEL EFFECT
9.5 HOT ELECTRON TRANSISTORS
9.6 RESONANT TUNNELLING TRANSISTOR
9.7 SINGLE ELECTRON TRANSISTOR
PROBLEMS
Chapter 10: Optoelectronic Devices Based on Nanostructures
10.1 INTRODUCTION
10.2 HETEROSTRUCTURE SEMICONDUCTOR LASERS
10.3 QUANTUM WELL SEMICONDUCTOR LASERS
10.4 VERTICAL CAVITY SURFACE EMITTING LASERS (VCSELs)
10.5 STRAINED QUANTUM WELL LASERS
10.6 QUANTUM DOT LASERS
10.7 QUANTUM WELL AND SUPERLATTICE PHOTODETECTORS
10.8 QUANTUM WELL MODULATORS
PROBLEMS
Index View less >
9780080445533
Applied physics
621.381 DUA-N
Nanotechnology for Microelectronics and Optoelectronics - New Delhi Elsevier 2006 - 279p.
Chapter 1: Mesoscopic Physics and Nanotechnologies
1.1 OUTLOOK OF THE BOOK
1.2 TRENDS IN NANOELECTRONICS AND OPTOELECTRONICS
1.3 CHARACTERISTIC LENGTHS IN MESOSCOPIC SYSTEMS
1.4 QUANTUM MECHANICAL COHERENCE
1.5 QUANTUM WELLS, WIRES, AND DOTS
1.6 DENSITY OF STATES AND DIMENSIONALITY
1.7 SEMICONDUCTOR HETEROSTRUCTURES
1.8 QUANTUM TRANSPORT
PROBLEMS
Chapter 2: Survey of Solid State Physics
2.1 INTRODUCTION
2.2 SHORT REVIEW OF QUANTUM MECHANICS
2.3 FREE ELECTRON MODEL OF A SOLID. DENSITY OF STATES FUNCTION
2.4 BLOCH THEOREM
2.5 ELECTRONS IN CRYSTALLINE SOLIDS
2.6 DYNAMICS OF ELECTRONS IN BANDS
2.7 LATTICE VIBRATIONS
2.8 PHONONS
PROBLEMS
Chapter 3: Review of Semiconductor Physics
3.1 INTRODUCTION
3.2 ENERGY BANDS IN TYPICAL SEMICONDUCTORS
3.3 INTRINSIC AND EXTRINSIC SEMICONDUCTORS
3.4 ELECTRON AND HOLE CONCENTRATIONS IN SEMICONDUCTORS
3.5 ELEMENTARY TRANSPORT IN SEMICONDUCTORS
3.6 DEGENERATE SEMICONDUCTORS
3.7 OPTICAL PROPERTIES OF SEMICONDUCTORS
PROBLEMS
Chapter 4: The Physics of Low-Dimensional Semiconductors
4.1 INTRODUCTION
4.2 BASIC PROPERTIES OF TWO-DIMENSIONAL SEMICONDUCTOR NANOSTRUCTURES
4.3 SQUARE QUANTUM WELL OF FINITE DEPTH
4.4 PARABOLIC AND TRIANGULAR QUANTUM WELLS
4.5 QUANTUM WIRES
4.6 QUANTUM DOTS
4.7 STRAINED LAYERS
4.8 EFFECT OF STRAIN ON VALENCE BANDS
4.9 BAND STRUCTURE IN QUANTUM WELLS
4.10 EXCITONIC EFFECTS IN QUANTUM WELLS
PROBLEMS
Chapter 5: Semiconductor Quantum Nanostructures and Superlattices
5.1 INTRODUCTION
5.2 MOSFET STRUCTURES
5.3 HETEROJUNCTIONS
5.4 QUANTUM WELLS
5.5 SUPERLATTICES
PROBLEMS
Chapter 6: Electric Field Transport in Nanostructures
6.1 INTRODUCTION
6.2 PARALLEL TRANSPORT
6.3 PERPENDICULAR TRANSPORT
6.4 QUANTUM TRANSPORT IN NANOSTRUCTURES
PROBLEMS
Chapter 7: Transport in Magnetic Fields and the Quantum Hall Effect
7.1 INTRODUCTION
7.2 EFFECT OF A MAGNETIC FIELD ON A CRYSTAL
7.3 LOW-DIMENSIONAL SYSTEMS IN MAGNETIC FIELDS
7.4 DENSITY OF STATES OF A 2D SYSTEM IN A MAGNETIC FIELD
7.5 THE AHARONOV–BOHM EFFECT
7.6 THE SHUBNIKOV–DE HAAS EFFECT
7.7 THE QUANTUM HALL EFFECT
PROBLEMS
Chapter 8: Optical and Electro-optical Processes in Quantum Heterostructures
8.1 INTRODUCTION
8.2 OPTICAL PROPERTIES OF QUANTUM WELLS AND SUPERLATTICES
8.3 OPTICAL PROPERTIES OF QUANTUM DOTS AND NANOCRYSTALS
8.4 ELECTRO-OPTICAL EFFECTS IN QUANTUM WELLS. QUANTUM CONFINED STARK EFFECT
8.5 ELECTRO-OPTICAL EFFECTS IN SUPERLATTICES. STARK LADDERS AND BLOCH OSCILLATIONS
PROBLEMS
Chapter 9: Electronic Devices Based on Nanostructures
9.1 INTRODUCTION
9.2 MODFETs
9.3 HETEROJUNCTION BIPOLAR TRANSISTORS
9.4 RESONANT TUNNEL EFFECT
9.5 HOT ELECTRON TRANSISTORS
9.6 RESONANT TUNNELLING TRANSISTOR
9.7 SINGLE ELECTRON TRANSISTOR
PROBLEMS
Chapter 10: Optoelectronic Devices Based on Nanostructures
10.1 INTRODUCTION
10.2 HETEROSTRUCTURE SEMICONDUCTOR LASERS
10.3 QUANTUM WELL SEMICONDUCTOR LASERS
10.4 VERTICAL CAVITY SURFACE EMITTING LASERS (VCSELs)
10.5 STRAINED QUANTUM WELL LASERS
10.6 QUANTUM DOT LASERS
10.7 QUANTUM WELL AND SUPERLATTICE PHOTODETECTORS
10.8 QUANTUM WELL MODULATORS
PROBLEMS
Index View less >
9780080445533
Applied physics
621.381 DUA-N