Engineered materials and metamaterials : design and fabrication /

"The field of metamaterials arose from a deeper understanding of how electromagnetic waves interact with materials and subwavelength-scaled scattering structures. This opened up the field of metamaterials or engineered materials through advances in understanding how material properties not foun...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autores principales: Dudley, Richard A., 1979- (Autor), Fiddy, M. A. (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Bellingham, Washington (1000 20th St. Bellingham WA 98225-6705 USA) : SPIE, 2017.
Colección:SPIE tutorial texts ; TT106.
Temas:
Metamaterials.
Optical materials.
Electronics > Materials.
Materials > Electric properties.
Materials > Magnetic properties.
High resolution imaging.
Métamatériaux.
Matériaux optiques.
Électronique > Matériaux.
Matériaux > Propriétés électriques.
Imagerie à haute résolution.
electrical properties.
TECHNOLOGY & ENGINEERING > Engineering (General)
TECHNOLOGY & ENGINEERING > Reference.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Preface
  • Acknowledgments
  • 1. Introduction: 1.1. Historical perspective; 1.2. Basic electromagnetic properties of materials; 1.3. Maxwell's equations; 1.4. Differential form of Maxwell's equations; 1.5. The six velocities of light; References
  • 2. Material properties: 2.1. Material classification; 2.2. Metals; 2.3. Dielectrics; 2.4. Equivalent-circuit overview
  • 3. Meta-atoms: 3.1. Overview; 3.2. Meta-atom building blocks; 3.3. Metal resonators; 3.4. Split-ring resonators; 3.5. Constitutive parameter estimation; 3.6. Metasurfaces; References
  • 4. Composite media and effective medium approximations: 4.1. Composite media; 4.2. Form-birefringent metamaterials; 4.3. Summary; References
  • 5. Anisotropic microwave metamaterials: 5.1. Form-birefringent materials: a case study; 5.2. Example microwave material; References; 6. Negative index: 6.1. History of negative index; 6.2. Graphical examples of wave propagation; References
  • 7. Numerical simulations: 7.1. Frequency-dependent numerical models; 7.2. Negative-index properties and computational restrictions; References
  • 8. Making smaller structures: optical metamaterials: 8.1. Material challenges; 8.2. Plasma waves and plasmonics; 8.3. Optical metamaterials; 8.4. Hyperbolic metamaterials; References
  • 9. Optical materials and fabrication challenges: 9.1. Thin films; 9.2. Thin dielectric gaps between metal surfaces; 9.3. Fabrication methods and challenges; 9.4. Process impact of RIE and EBL; 9.5. Lithographic techniques; References.
  • 10. Superresolved imaging: 10.1. Superresolution using metamaterials: a case study; 10.2. The inverse scattering problem; 10.3. Degrees of freedom; 10.4. Numerical examples; 10.5. Perfect imaging; 10.6. Slab imaging example; 10.7. Compressive sampling
  • References
  • Index.

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