Theory of Itinerant Electron Magnetism
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Theory of Itinerant Electron Magnetism
Kuebler, Juergen
Oxford University Press
09/2021
544
Dura
Inglês
9780192895639
15 a 20 dias
1188
Descrição não disponível.
Introduction
1.1: Basic Facts
1.2: Itinerant electrons
1.3: How to proceed
Density-Functional Theory
2.1: Born-Oppenheimer approximation
2.2: Hartree-Fock approximation
2.3: Density-functional theory
2.4: The electron spin: Dirac theory
2.5: Spin-density-functional theory
2.6: The local-density approximation (LDA)
2.7: Nonuniformly magnetized systems
2.8: The generalized gradient approximation (GGA)
Energy-Band Theory
3.1: Bloch's theorem
3.2: Plane waves, orthogonalized plane waves and Pseudopotentials
3.3: Augmented plane waves and Green's functions
3.4: Linear methods
Electronic Structure and Magnetism
4.1: Introduction and simple concepts
4.2: The magnetic susceptibility
4.3: Elementary magnetic metals
4.4: Magnetic compounds
4.5: Multilayers
4.6: Relativistic eects
4.7: Berry Phase effects in solids
4.8: Weyl Fermions
4.9: Real-case Weyl Fermions
Magnetism at Finite Temperatures
5.1: Density-functional theory at T > 0
5.2: Adiabatic spin dynamics
5.3: Mean-field theories
5.4: Spin uctuations
5.5: Magnetic Skyrmions
5.6: High-temperature approaches
References
1.1: Basic Facts
1.2: Itinerant electrons
1.3: How to proceed
Density-Functional Theory
2.1: Born-Oppenheimer approximation
2.2: Hartree-Fock approximation
2.3: Density-functional theory
2.4: The electron spin: Dirac theory
2.5: Spin-density-functional theory
2.6: The local-density approximation (LDA)
2.7: Nonuniformly magnetized systems
2.8: The generalized gradient approximation (GGA)
Energy-Band Theory
3.1: Bloch's theorem
3.2: Plane waves, orthogonalized plane waves and Pseudopotentials
3.3: Augmented plane waves and Green's functions
3.4: Linear methods
Electronic Structure and Magnetism
4.1: Introduction and simple concepts
4.2: The magnetic susceptibility
4.3: Elementary magnetic metals
4.4: Magnetic compounds
4.5: Multilayers
4.6: Relativistic eects
4.7: Berry Phase effects in solids
4.8: Weyl Fermions
4.9: Real-case Weyl Fermions
Magnetism at Finite Temperatures
5.1: Density-functional theory at T > 0
5.2: Adiabatic spin dynamics
5.3: Mean-field theories
5.4: Spin uctuations
5.5: Magnetic Skyrmions
5.6: High-temperature approaches
References
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
Introduction
1.1: Basic Facts
1.2: Itinerant electrons
1.3: How to proceed
Density-Functional Theory
2.1: Born-Oppenheimer approximation
2.2: Hartree-Fock approximation
2.3: Density-functional theory
2.4: The electron spin: Dirac theory
2.5: Spin-density-functional theory
2.6: The local-density approximation (LDA)
2.7: Nonuniformly magnetized systems
2.8: The generalized gradient approximation (GGA)
Energy-Band Theory
3.1: Bloch's theorem
3.2: Plane waves, orthogonalized plane waves and Pseudopotentials
3.3: Augmented plane waves and Green's functions
3.4: Linear methods
Electronic Structure and Magnetism
4.1: Introduction and simple concepts
4.2: The magnetic susceptibility
4.3: Elementary magnetic metals
4.4: Magnetic compounds
4.5: Multilayers
4.6: Relativistic eects
4.7: Berry Phase effects in solids
4.8: Weyl Fermions
4.9: Real-case Weyl Fermions
Magnetism at Finite Temperatures
5.1: Density-functional theory at T > 0
5.2: Adiabatic spin dynamics
5.3: Mean-field theories
5.4: Spin uctuations
5.5: Magnetic Skyrmions
5.6: High-temperature approaches
References
1.1: Basic Facts
1.2: Itinerant electrons
1.3: How to proceed
Density-Functional Theory
2.1: Born-Oppenheimer approximation
2.2: Hartree-Fock approximation
2.3: Density-functional theory
2.4: The electron spin: Dirac theory
2.5: Spin-density-functional theory
2.6: The local-density approximation (LDA)
2.7: Nonuniformly magnetized systems
2.8: The generalized gradient approximation (GGA)
Energy-Band Theory
3.1: Bloch's theorem
3.2: Plane waves, orthogonalized plane waves and Pseudopotentials
3.3: Augmented plane waves and Green's functions
3.4: Linear methods
Electronic Structure and Magnetism
4.1: Introduction and simple concepts
4.2: The magnetic susceptibility
4.3: Elementary magnetic metals
4.4: Magnetic compounds
4.5: Multilayers
4.6: Relativistic eects
4.7: Berry Phase effects in solids
4.8: Weyl Fermions
4.9: Real-case Weyl Fermions
Magnetism at Finite Temperatures
5.1: Density-functional theory at T > 0
5.2: Adiabatic spin dynamics
5.3: Mean-field theories
5.4: Spin uctuations
5.5: Magnetic Skyrmions
5.6: High-temperature approaches
References
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
