Superlattice to nanoelectronics 1st Edition by Raphael Tsu ISBN 0080455689 9780080455686
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ISBN 10: 0080455689
ISBN 13: 9780080455686
Author: Raphael Tsu
Superlattice to Nanoelectronics provides a historical overview of the early work performed by Tsu and Esaki, to orient those who want to enter into this nanoscience. It describes the fundamental concepts and goes on to answer many questions about todays ‘Nanoelectronics’. It covers the applications and types of devices which have been produced, many of which are still in use today. This historical perspective is important as a guide to what and how technology and new fundamental ideas are introduced and developed.
The author communicates a basic understanding of the physics involved from first principles, whilst adding new depth, using simple mathematics and explanation of the background essentials.
Superlattice to nanoelectronics 1st Table of contents:
1. Superlattice
1.1. THE BIRTH OF THE MAN-MADE SUPERLATTICE
1.2. A MODEL FOR THE CREATION OF MAN-MADE ENERGY BANDS
1.3. TRANSPORT PROPERTIES OF A SUPERLATTICE
1.4. MORE RIGOROUS DERIVATION OF THE NEGATIVE DIFFERENTIAL CONDUCTANCE
1.5. RESPONSE OF A TIME-DEPENDENT ELECTRIC FIELD
1.6. NDC FROM THE HOPPING MODEL AND ELECTRIC FIELD INDUCED LOCALIZATION
1.7. EXPERIMENTS
1.8. TYPE II SUPERLATTICE
1.9. PHYSICAL REALIZATION AND CHARACTERIZATION OF A SUPERLATTICE
1.10. SUMMARY
REFERENCES
2. Resonant Tunneling Via Man-Made Quantum Well States
2.1. THE BIRTH OF RESONANT TUNNELING
2.2. SOME FUNDAMENTALS
2.3. CONDUCTANCE FROM THE TSU–ESAKI FORMULA
2.4. TUNNELING TIME FROM THE TIME-DEPENDENT SCHRÖDINGER EQUATION
2.5. DAMPING IN RESONANT TUNNELING
2.6. VERY SHORT ℓ AND w FOR AN AMORPHOUS QUANTUM WELL
2.7. SELF-CONSISTENT POTENTIAL CORRECTION OF DBRT
2.8. EXPERIMENTAL CONFIRMATION OF RESONANT TUNNELING
2.9. INSTABILITY IN RTD
2.10. SUMMARY
REFERENCES
3. Optical Properties and Raman Scattering in Man-Made Quantum Systems
3.1. OPTICAL ABSORPTION IN A SUPERLATTICE
3.2. PHOTOCONDUCTIVITY IN A SUPERLATTICE
3.3. RAMAN SCATTERING IN A SUPERLATTICE AND QUANTUM WELL
3.4. SUMMARY
REFERENCES
4. Dielectric Function and Doping of a Superlattice
4.1. DIELECTRIC FUNCTION OF A SUPERLATTICE AND A QUANTUM WELL
4.2. DOPING A SUPERLATTICE
4.3. SUMMARY
REFERENCES
5. Quantum Step and Activation Energy
5.1. OPTICAL PROPERTIES OF QUANTUM STEPS
5.2. DETERMINATION OF ACTIVATION ENERGY IN QUANTUM WELLS
5.3. SUMMARY
REFERENCES
6. Semiconductor Atomic Superlattice (SAS)
6.1. SILICON-BASED QUANTUM WELLS
6.2. Si–INTERFACE ADSORBED GAS (IAG) SUPERLATTICE
6.3. AMORPHOUS SILICON/SILICON OXIDE SUPERLATTICE
6.4. SILICON–OXYGEN (Si–O) SUPERLATTICE
6.5. ESTIMATE OF THE BAND-EDGE ALIGNMENT USING ATOMIC STATES
6.6. ESTIMATE OF THE BAND-EDGE ALIGNMENT WITH HOMO–LUMO
6.7. ESTIMATION OF STRAIN FROM A BALL AND STICK MODEL
6.8. ELECTROLUMINESCENCE AND PHOTOLUMINESCENCE
6.9. TRANSPORT THROUGH A Si–O SUPERLATTICE
6.10. COMPARISON OF A Si–O SUPERLATTICE AND A Ge–Si MONOLAYER SUPERLATTICE
6.11. SUMMARY
REFERENCES
7. Si Quantum Dots
7.1. ENERGY STATES OF SILICON QUANTUM DOTS
7.2. RESONANT TUNNELING IN SILICON QUANTUM DOTS
7.3. SLOW OSCILLATIONS AND HYSTERESIS
7.4. AVALANCHE MULTIPLICATION FROM RESONANT TUNNELING
7.5. INFLUENCE OF LIGHT AND REPEATABILITY UNDER MULTIPLE SCANS
7.6. SUMMARY
REFERENCES
8. Capacitance, Dielectric Constant and Doping Quantum Dots
8.1. CAPACITANCE OF SILICON QUANTUM DOTS
8.2. DIELECTRIC CONSTANT OF A SILICON QUANTUM DOT
8.3. DOPING A SILICON QUANTUM DOT
8.4. SUMMARY
REFERENCES
9. Porous Silicon
9.1. POROUS SILICON – LIGHT EMITTING SILICON
9.2. POROUS SILICON – OTHER APPLICATIONS
9.3. SUMMARY
REFERENCES
10. Some Novel Devices
10.1. COLD CATHODE
10.2. SATURATION INTENSITY OF PbS QUANTUM DOTS
10.3. MULTIPOLE ELECTRODE HETEROJUNCTION HYBRID STRUCTURES
10.4. SOME FUNDAMENTAL ISSUES: MAINLY DIFFICULTIES
10.5. COMMENTS ON QUANTUM COMPUTING
10.6. SUMMARY
REFERENCES
11. Quantum Impedance of Electrons
11.1. LANDAUER CONDUCTANCE FORMULA
11.2. ELECTRON QUANTUM WAVEGUIDE (EQW)
11.3. WAVE IMPEDANCE OF ELECTRONS
11.4. SUMMARY
REFERENCES
12. Nanoelectronics: Where Are You?
REFERENCES
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Tags: Raphael Tsu, Superlattice, nanoelectronics