Dynamical properties in nanostructured and low-dimensional materials /

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The dramatic advances that started two decades ago in the growth, fabrication and characterisation of low-dimensional materials have continued, with important developments in the seven years since the first edition of this book.

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Cottam, Michael G. (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) : IOP Publishing, [2022]
Edición:Second edition.
Colección:IOP (Series). Release 22.
IOP ebooks. 2022 collection.
Temas:
Nanostructured materials.
Condensed matter physics (liquid state & solid state physics)
Condensed matter.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • 1. Introduction
  • 1.1. Types of excitations or waves
  • 1.2. Survey of different nanostructures
  • 1.3. Experimental techniques for dynamic properties
  • 1.4. Theoretical methods for dynamic properties
  • 1.5. Photonic band gaps in periodic structures
  • 2. Phonons
  • 2.1. One-dimensional models of lattice dynamics for films
  • 2.2. Higher-dimensional lattice dynamics for films
  • 2.3. Elastic waves for single surfaces and films
  • 2.4. Experimental studies
  • 2.5. Phonons in multilayers and superlattices
  • 2.6. Phononic crystals
  • 3. Exchange-dominated magnetic excitations
  • 3.1. Regimes of magnetization dynamics
  • 3.2. Heisenberg ferromagnetic films
  • 3.3. Heisenberg antiferromagnetic films
  • 3.4. One- and two-dimensional magnetic systems
  • 3.5. More types of exchange interactions
  • 3.6. Magnetic superlattices and magnonic crystals
  • 4. Dipole-exchange magnetic excitations
  • 4.1. Dipole-dominated spin waves in films
  • 4.2. Dipole-dominated spin waves in wires and tubes
  • 4.3. Dipole-exchange waves in films
  • 4.4. Magnetic nanowires and stripes
  • 4.5. Magnetic disks and rings
  • 4.6. Magnetic superlattices
  • 4.7. Magnonic crystals
  • 5. Electronic and plasmonic excitations
  • 5.1. Electronic surface states
  • 5.2. Graphene sheets and ribbons
  • 5.3. Bulk dielectric functions
  • 5.4. Plasmonics in two dimensions
  • 5.5. Bulk-slab model for superlattice plasmons
  • 6. Polaritons
  • 6.1. Phonon-polaritons
  • 6.2. Plasmon-polaritons
  • 6.3. Graphene plasmonics
  • 6.4. Magnon-polaritons
  • 6.5. Other types of polaritons
  • 7. Mixed excitations
  • 7.1. Magnetoelastic waves
  • 7.2. Piezoelectric waves
  • 7.3. Ferroelectric materials
  • 7.4. Multiferroic materials
  • 8. Nonlinear dynamics for nonmagnetic excitations
  • 8.1. Nonlinearities in optics
  • 8.2. Nonlinearities for phonons
  • 8.3. Introduction to solitons
  • 8.4. Some applications to low-dimensional systems
  • 8.5. Gap solitons in nonlinear optics
  • 9. Nonlinear dynamics for magnetic excitations
  • 9.1. Fundamentals of magnetic nonlinearities
  • 9.2. Instability of magnons under microwave pumping
  • 9.3. Magnetic solitons
  • 9.4. Other applications to magnetic systems
  • 9.5. Hybrid magnons in cavities.

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