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This text brings together traditional solid-state approaches from the 20th century with developments of the early part of the 21st century, to reach an understanding of semiconductor physics in its multifaceted forms. It reveals how an understanding of what happens within the material can lead to insights into what happens in its use.
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This text brings together traditional solid-state approaches from the 20th century with developments of the early part of the 21st century, to reach an understanding of semiconductor physics in its multifaceted forms. It reveals how an understanding of what happens within the material can lead to insights into what happens in its use.
Produktdetails
- Produktdetails
- Verlag: Oxford University Press, USA
- Seitenzahl: 832
- Erscheinungstermin: 22. Oktober 2020
- Englisch
- Abmessung: 254mm x 193mm x 51mm
- Gewicht: 1882g
- ISBN-13: 9780198759867
- ISBN-10: 019875986X
- Artikelnr.: 56847226
- Verlag: Oxford University Press, USA
- Seitenzahl: 832
- Erscheinungstermin: 22. Oktober 2020
- Englisch
- Abmessung: 254mm x 193mm x 51mm
- Gewicht: 1882g
- ISBN-13: 9780198759867
- ISBN-10: 019875986X
- Artikelnr.: 56847226
Sandip Tiwari is Charles N. Mellowes Professor in Engineering at Cornell University and Visiting Professor at Université de Paris-Sud (Orsay). His contributions to engineering have included the invention of nanocrystal memories, as a group researcher in the first demonstration of SiGe bipolar transistor and a variety of others of fundamental importance--theoretical and experimental--in electronic and optical devices, circuits and architectures. He was founding editor-in-chief of IEEE's Transactions on Nanotechnology. Among the various recognitions of his contributions are the Cledo Brunetti award of IEEE (2007), the Young Scientist Award from Institute of Physics' GaAs & Related Compounds (2003), the Distinguished Alumni award of IIT Kanpur (2002), and the fellowships of IEEE (1994) and APS (1998).
1: Hamiltonians and solution techniques
2: Entropy, information and energy
3: Waves and particles in the crystal
4: Bandstructures
5: Semiconductor surfaces
6: Semiconductor interfaces and junctions
7: Point perturbations
8: Transport and evolution of classical and quantum ensembles
9: Scattering-constrained dynamics
10: Major scattering processes
11: Particle generation and recombination
12: Light interactions with semiconductors
13: Causality and Green's functions
14: Quantum to macroscale and linear response
15: Onsager relationships
16: Noise
17: Stress and strain effects
18: High permittivity dielectrics
19: Remote processes
20: Quantum confinement and monolayer semiconductors
App. A: Integral transform theorems
App. B: Various useful functions
App. C: Random processes
App. D: Calculus of variation and the Lagrangian method
App. E: A thermodynamics primer
App. F: Maxwell-Boltzmann distribution function
App. G: Spin and spin matrices
App. H: Density of states
App. I: Oscillator strength
App. J: Effective mass tensor
App. K: A and B coefficients, and spontaneous and stimulated emission
App. L: Helmholtz theorem and vector splitting
App. M: Mode coupling and Purcell effect
App. M: Vector and scalar potentials
App. O: Analyticity, Kramers-Kronig and Hilbert transforms
App. P: Particle velocities
2: Entropy, information and energy
3: Waves and particles in the crystal
4: Bandstructures
5: Semiconductor surfaces
6: Semiconductor interfaces and junctions
7: Point perturbations
8: Transport and evolution of classical and quantum ensembles
9: Scattering-constrained dynamics
10: Major scattering processes
11: Particle generation and recombination
12: Light interactions with semiconductors
13: Causality and Green's functions
14: Quantum to macroscale and linear response
15: Onsager relationships
16: Noise
17: Stress and strain effects
18: High permittivity dielectrics
19: Remote processes
20: Quantum confinement and monolayer semiconductors
App. A: Integral transform theorems
App. B: Various useful functions
App. C: Random processes
App. D: Calculus of variation and the Lagrangian method
App. E: A thermodynamics primer
App. F: Maxwell-Boltzmann distribution function
App. G: Spin and spin matrices
App. H: Density of states
App. I: Oscillator strength
App. J: Effective mass tensor
App. K: A and B coefficients, and spontaneous and stimulated emission
App. L: Helmholtz theorem and vector splitting
App. M: Mode coupling and Purcell effect
App. M: Vector and scalar potentials
App. O: Analyticity, Kramers-Kronig and Hilbert transforms
App. P: Particle velocities
1: Hamiltonians and solution techniques
2: Entropy, information and energy
3: Waves and particles in the crystal
4: Bandstructures
5: Semiconductor surfaces
6: Semiconductor interfaces and junctions
7: Point perturbations
8: Transport and evolution of classical and quantum ensembles
9: Scattering-constrained dynamics
10: Major scattering processes
11: Particle generation and recombination
12: Light interactions with semiconductors
13: Causality and Green's functions
14: Quantum to macroscale and linear response
15: Onsager relationships
16: Noise
17: Stress and strain effects
18: High permittivity dielectrics
19: Remote processes
20: Quantum confinement and monolayer semiconductors
App. A: Integral transform theorems
App. B: Various useful functions
App. C: Random processes
App. D: Calculus of variation and the Lagrangian method
App. E: A thermodynamics primer
App. F: Maxwell-Boltzmann distribution function
App. G: Spin and spin matrices
App. H: Density of states
App. I: Oscillator strength
App. J: Effective mass tensor
App. K: A and B coefficients, and spontaneous and stimulated emission
App. L: Helmholtz theorem and vector splitting
App. M: Mode coupling and Purcell effect
App. M: Vector and scalar potentials
App. O: Analyticity, Kramers-Kronig and Hilbert transforms
App. P: Particle velocities
2: Entropy, information and energy
3: Waves and particles in the crystal
4: Bandstructures
5: Semiconductor surfaces
6: Semiconductor interfaces and junctions
7: Point perturbations
8: Transport and evolution of classical and quantum ensembles
9: Scattering-constrained dynamics
10: Major scattering processes
11: Particle generation and recombination
12: Light interactions with semiconductors
13: Causality and Green's functions
14: Quantum to macroscale and linear response
15: Onsager relationships
16: Noise
17: Stress and strain effects
18: High permittivity dielectrics
19: Remote processes
20: Quantum confinement and monolayer semiconductors
App. A: Integral transform theorems
App. B: Various useful functions
App. C: Random processes
App. D: Calculus of variation and the Lagrangian method
App. E: A thermodynamics primer
App. F: Maxwell-Boltzmann distribution function
App. G: Spin and spin matrices
App. H: Density of states
App. I: Oscillator strength
App. J: Effective mass tensor
App. K: A and B coefficients, and spontaneous and stimulated emission
App. L: Helmholtz theorem and vector splitting
App. M: Mode coupling and Purcell effect
App. M: Vector and scalar potentials
App. O: Analyticity, Kramers-Kronig and Hilbert transforms
App. P: Particle velocities