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This introductory text develops the reader's fundamental understanding of core principles and experimental aspects underlying the operation of nanoelectronic devices. The author makes a thorough and systematic presentation of electron transport in quantum-confined systems.
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This introductory text develops the reader's fundamental understanding of core principles and experimental aspects underlying the operation of nanoelectronic devices. The author makes a thorough and systematic presentation of electron transport in quantum-confined systems.
Produktdetails
- Produktdetails
- Verlag: Taylor & Francis Ltd (Sales)
- Seitenzahl: 410
- Erscheinungstermin: 21. Juli 2020
- Englisch
- Abmessung: 279mm x 216mm x 25mm
- Gewicht: 1320g
- ISBN-13: 9780815384267
- ISBN-10: 0815384262
- Artikelnr.: 59927484
- Verlag: Taylor & Francis Ltd (Sales)
- Seitenzahl: 410
- Erscheinungstermin: 21. Juli 2020
- Englisch
- Abmessung: 279mm x 216mm x 25mm
- Gewicht: 1320g
- ISBN-13: 9780815384267
- ISBN-10: 0815384262
- Artikelnr.: 59927484
Vinod Kumar Khanna is a former emeritus scientist, CSIR (Council of Scientific & Industrial Research) and emeritus professor, AcSIR (Academy of Scientific & Innovative Research), India. He is a retired Chief Scientist and Head, MEMS & Microsensors Group, CSIR-CEERI (CSIR-Central Electronics Engineering Research Institute), Pilani (Rajasthan) and Professor, AcSIR, India.
Nanoelectronics and Mesoscopic Physics. Part I: Quantum Mechanics for
Nanoelectronics. Origins of Quantum Theory. The Schrodinger Wave Equation.
Operator Methods and Postulates of Quantum Mechanics. Particle-in-a-Box and
Related Problems. The Hydrogen Atom. Part II: Condensed Matter Physics for
Nanoelectronics. Drude-Lorentz Free Electron Model. Sommerfield Free
Electron Fermi Gas Model. Kronig-Penney Periodic Potential Model. Part III:
Electron Behavior in Nanostructures. Quantum Confinement and Electronic
Structure of Quantum Dots. Electrons in Quantum Wires and Landauer-Büttiker
Formalism. Electrons in Quantum Wells. Part IV: Green's Function Method for
Nanoelectronic Device Modeling. Dirac Delta and Green's Function
Preliminaries. Method of Finite Differences and Self Energy of the Leads.
Non-Equilibrium Green's Function (NEGF) Formalism. Part V: Fabrication and
Characterization of Nanostructures. Fabrication Tools. Characterization
Facilities. Part VI: Exemplar Nanoelectronic Devices. Resonant Tunneling
Diodes. Nanoscale MOSFETs and Similar Devices. High-Electron Mobility
Transistors. Single Electron Transistors. Heterostructure Optoelectronic
Devices. Index
Nanoelectronics. Origins of Quantum Theory. The Schrodinger Wave Equation.
Operator Methods and Postulates of Quantum Mechanics. Particle-in-a-Box and
Related Problems. The Hydrogen Atom. Part II: Condensed Matter Physics for
Nanoelectronics. Drude-Lorentz Free Electron Model. Sommerfield Free
Electron Fermi Gas Model. Kronig-Penney Periodic Potential Model. Part III:
Electron Behavior in Nanostructures. Quantum Confinement and Electronic
Structure of Quantum Dots. Electrons in Quantum Wires and Landauer-Büttiker
Formalism. Electrons in Quantum Wells. Part IV: Green's Function Method for
Nanoelectronic Device Modeling. Dirac Delta and Green's Function
Preliminaries. Method of Finite Differences and Self Energy of the Leads.
Non-Equilibrium Green's Function (NEGF) Formalism. Part V: Fabrication and
Characterization of Nanostructures. Fabrication Tools. Characterization
Facilities. Part VI: Exemplar Nanoelectronic Devices. Resonant Tunneling
Diodes. Nanoscale MOSFETs and Similar Devices. High-Electron Mobility
Transistors. Single Electron Transistors. Heterostructure Optoelectronic
Devices. Index
Nanoelectronics and Mesoscopic Physics. Part I: Quantum Mechanics for Nanoelectronics. Origins of Quantum Theory. The Schrodinger Wave Equation. Operator Methods and Postulates of Quantum Mechanics. Particle-in-a-Box and Related Problems. The Hydrogen Atom. Part II: Condensed Matter Physics for Nanoelectronics. Drude-Lorentz Free Electron Model. Sommerfield Free Electron Fermi Gas Model. Kronig-Penney Periodic Potential Model. Part III: Electron Behavior in Nanostructures. Quantum Confinement and Electronic Structure of Quantum Dots. Electrons in Quantum Wires and Landauer-Büttiker Formalism. Electrons in Quantum Wells. Part IV: Green's Function Method for Nanoelectronic Device Modeling. Dirac Delta and Green's Function Preliminaries. Method of Finite Differences and Self Energy of the Leads. Non-Equilibrium Green's Function (NEGF) Formalism. Part V: Fabrication and Characterization of Nanostructures. Fabrication Tools. Characterization Facilities. Part VI: Exemplar Nanoelectronic Devices. Resonant Tunneling Diodes. Nanoscale MOSFETs and Similar Devices. High-Electron Mobility Transistors. Single Electron Transistors. Heterostructure Optoelectronic Devices. Index
Nanoelectronics and Mesoscopic Physics. Part I: Quantum Mechanics for
Nanoelectronics. Origins of Quantum Theory. The Schrodinger Wave Equation.
Operator Methods and Postulates of Quantum Mechanics. Particle-in-a-Box and
Related Problems. The Hydrogen Atom. Part II: Condensed Matter Physics for
Nanoelectronics. Drude-Lorentz Free Electron Model. Sommerfield Free
Electron Fermi Gas Model. Kronig-Penney Periodic Potential Model. Part III:
Electron Behavior in Nanostructures. Quantum Confinement and Electronic
Structure of Quantum Dots. Electrons in Quantum Wires and Landauer-Büttiker
Formalism. Electrons in Quantum Wells. Part IV: Green's Function Method for
Nanoelectronic Device Modeling. Dirac Delta and Green's Function
Preliminaries. Method of Finite Differences and Self Energy of the Leads.
Non-Equilibrium Green's Function (NEGF) Formalism. Part V: Fabrication and
Characterization of Nanostructures. Fabrication Tools. Characterization
Facilities. Part VI: Exemplar Nanoelectronic Devices. Resonant Tunneling
Diodes. Nanoscale MOSFETs and Similar Devices. High-Electron Mobility
Transistors. Single Electron Transistors. Heterostructure Optoelectronic
Devices. Index
Nanoelectronics. Origins of Quantum Theory. The Schrodinger Wave Equation.
Operator Methods and Postulates of Quantum Mechanics. Particle-in-a-Box and
Related Problems. The Hydrogen Atom. Part II: Condensed Matter Physics for
Nanoelectronics. Drude-Lorentz Free Electron Model. Sommerfield Free
Electron Fermi Gas Model. Kronig-Penney Periodic Potential Model. Part III:
Electron Behavior in Nanostructures. Quantum Confinement and Electronic
Structure of Quantum Dots. Electrons in Quantum Wires and Landauer-Büttiker
Formalism. Electrons in Quantum Wells. Part IV: Green's Function Method for
Nanoelectronic Device Modeling. Dirac Delta and Green's Function
Preliminaries. Method of Finite Differences and Self Energy of the Leads.
Non-Equilibrium Green's Function (NEGF) Formalism. Part V: Fabrication and
Characterization of Nanostructures. Fabrication Tools. Characterization
Facilities. Part VI: Exemplar Nanoelectronic Devices. Resonant Tunneling
Diodes. Nanoscale MOSFETs and Similar Devices. High-Electron Mobility
Transistors. Single Electron Transistors. Heterostructure Optoelectronic
Devices. Index
Nanoelectronics and Mesoscopic Physics. Part I: Quantum Mechanics for Nanoelectronics. Origins of Quantum Theory. The Schrodinger Wave Equation. Operator Methods and Postulates of Quantum Mechanics. Particle-in-a-Box and Related Problems. The Hydrogen Atom. Part II: Condensed Matter Physics for Nanoelectronics. Drude-Lorentz Free Electron Model. Sommerfield Free Electron Fermi Gas Model. Kronig-Penney Periodic Potential Model. Part III: Electron Behavior in Nanostructures. Quantum Confinement and Electronic Structure of Quantum Dots. Electrons in Quantum Wires and Landauer-Büttiker Formalism. Electrons in Quantum Wells. Part IV: Green's Function Method for Nanoelectronic Device Modeling. Dirac Delta and Green's Function Preliminaries. Method of Finite Differences and Self Energy of the Leads. Non-Equilibrium Green's Function (NEGF) Formalism. Part V: Fabrication and Characterization of Nanostructures. Fabrication Tools. Characterization Facilities. Part VI: Exemplar Nanoelectronic Devices. Resonant Tunneling Diodes. Nanoscale MOSFETs and Similar Devices. High-Electron Mobility Transistors. Single Electron Transistors. Heterostructure Optoelectronic Devices. Index