Electronic Conduction by Xanthakis, John P.;

Classical and Quantum Theory to Nanoelectronic Devices

Series: Textbook Series in Physical Sciences;

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Product details:

Edition number 1
Publisher CRC Press
Date of Publication 31 May 2023

ISBN 9780367639198
Binding Paperback
No. of pages310 pages
Size 254x178 mm
Weight 570 g
Language English
Illustrations 174 Illustrations, black & white; 2 Tables, black & white

Short description:

This book provides a concise, complete introduction to the fundamental principles of electronic conduction in microelectronic and nanoelectronic devices, with an emphasis on integrating the quantum aspects of conduction.

Long description:

Electronic Conduction: Classical and Quantum Theory to Nanoelectronic Devices provides a concise, complete introduction to the fundamental principles of electronic conduction in microelectronic and nanoelectronic devices, with an emphasis on integrating the quantum aspects of conduction.

The chapter coverage begins by presenting the classical theory of conduction, including introductory chapters on quantum mechanics and the solid state, then moving to a complete presentation of essential theory for understanding modern electronic devices. The author?s unique approach is applicable to microscale and nanoscale device simulation, which is particularly timely given the explosion in the nanoelectronics field.

Features

Self-contained

Gives a complete account of classical and quantum aspects of conduction in nanometer scale devices

Emphasises core principles, the book can be useful to electrical engineers and material scientists, and no prior course in semiconductors is necessary

Highlights the bridge to modern electronics, first presenting the physics, and then the engineering complications related to quantum behaviour

Includes many clear, illustrative diagrams and chapter problem sets

Gives an account of post-Silicon devices such as the GaAs MOSFET, the CNT-FET and the vacuum transistor

Showcases why quantum mechanics is necessary with modern devices due to their size and corresponding electron transport properties

Discusses all the issues that will enable readers to conduct their own research?

I. Prerequisites: Quantum Mechanics and The Electronic States in Solids. 1. Quantum Mechanics. 1.1. The two-slit experiment. 1.2. The Schroedinger Equation. 1.3. Particle in a Rectangular Quantum Box. 1.4. Heisenberg?s Uncertainty Principle. 1.5. The Pauli Principle and the Fermi Dirac Probability. 1.6. The Hydrogen atom and the atoms of the Periodic Table. 1.7. Barrier Penetration and Tunneling. 1.8. Probability Current Density. 2. Electron States in Solids. 2.1. Qualitative Description of Energy Bands in Solids. 2.2. The k-space and Bloch?s Theorem. 2.3. The LCAO method. 2.4. Quick Revision of the concept of a Hole and Doping. 2.5. Velocity of electrons in Solids. 2.6. The concept of Effective Mass. 2.7. Concentration of Carriers in Semiconductors and Metals. 2.8. The Effective Mass Equation. II. Theory Of Conduction. 3. Simple Classical Theory of Conduction. 3.1. External voltages and Fermi levels. 3.2. Collisions and drift mobility. 3.3. Mechanisms of scattering. 3.4. Recombination of carriers. 3.5 Diffusion Current. 3.6. Continuity Equations. 3.7. The ideal PN junction at equilibrium. 3.8. The ideal PN junction under bias. 3.9. The non-ideal PN junction. 3.10. The Metal-Semiconductor or Schottky junction. 4. Advanced Classical Theory of conduction. 4.1. The need for a better classical theory of conduction. 4.2. The Boltzman equation. 4.3. Solution of the Boltzman equation by the relaxation time approximation. 4.4. Application of an Electric Field. 4.5. Diffusion Currents. 4.6. General Expression for the Current Density. 4.7. The Seebeck-Thermoelectric Effect. 4.8. Saturation of drift velocity. 4.9. The Gunn Effect and velocity overshoot. 4.10. The classical Hall Effect. Chapter 5. The Quantum Theory of Conduction. 5.1. Critique of the Boltzmann Equation and Regimes of conduction. 5.2. Electronic Structure of Low-dimensional Systems. 5.3. The Landauer Formalism. 5.4. The Effective Mass Equation for Heterostructures. 5.5. Transmission Matrices and Airy Function. 5.6. The Resonant Tunneling Diode RTD. III. Devices. Chapter 6: Field Emission and Vacuum Devices. 6.1. Introduction. 6.2. The One-dimensional WKB Equation. 6.3. Field Emission from Planar Surfaces. 6.4. The Three-dimensional WKB Problem. 6.5. Field Emission from Curved Surfaces. 6.6. The Vacuum Transistor. Chapter 7. The MOSFET. 7.1. Basic Operation. 7.2. Simple Classical Theory of the MOSFET. 7.3. Advanced Classical Theory of the MOSFET. 7.4. Quantum Theory of the MOSFET. 7.5. Time-Dependent Performance and Moores? law. 7.6. Non-Planar Si MOSFETs and the FinFET. Chapter 8. Post ?Si FETs. 8.1. Introduction. 8.2. Simple Theory of the HEMT or MODFET. 8.3. Advanced theory of the HEMT. 8.4. The III-V MOSFET. 8.5. The Carbon Nanotube FET, CNTFET. Appendices. A1. Angular Momentum and Spin. A2. Lattice Vibrations. A3. Calculation of Impurity States in Semiconductors. A4. Direct and Indirect Gap Semiconductors and Optical Properties.