Near-field radiative heat transfer across nanometer vacuum gaps : fundamentals and applications /

Near-Field Radiative Heat Transfer across Nanometer Vacuum Gaps provides an in-depth description of fundamentals and application of near-field radiative heat transfer. When the vacuum gap between two media is on the order of nanometers, heat transfer can exceed that between blackbodies. This book in...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Basu, Soumyadipta (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Oxford, UK : William Andrew is an imprint of Elsevier, 2016.
Colección:Micro & nano technologies.
Temas:
Heat > Transmission.
Chaleur > Transmission.
heat transmission.
TECHNOLOGY & ENGINEERING > Mechanical.
Heat > Transmission
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Front Cover; Near-Field Radiative Heat Transfer across Nanometer Vacuum Gaps; Dedication; Near-Field Radiative Heat Transfer across NanometerVacuum Gaps; Copyright; Contents; Preface; 1
  • Introduction and Fundamental Concepts; 2
  • Numerical Solution of Near-Field Thermal Radiation; 3
  • Dielectric Function and Surface Waves in Near-Field Radiation; 4
  • Near-Field Heat Transfer Between Parallel Media; 5
  • Near-Field Heat Transfer Between Nonparallel Media and Nanostructures; 6
  • Measurement of Thermal Radiation; 7
  • Applications of Near-Field Thermal Radiation; Index; Back Cover
  • 1.1 heat transfer fundamentals1.2 entropy flow and generation in radiative transfer between surfaces; 1.3 near-field radiative heat transfer; 1.4 entropy generation in near-field thermal radiation; 1.5 conclusion; references; 2.1 scattering matrix method; 2.2 finite difference time domain; 2.3 wiener chaos expansion method; 2.4 fluctuating-surface current formulation; 2.5 thermal discrete dipole approximation (t-dda); 2.6 conclusion; references; 3.1 dielectric function; 3.2 evanescent waves and surface polaritons; 3.3 conclusion; references; 4.1 semi-infinite parallel media
  • 4.2 maximum near-field heat transfer between parallel plates at nanometer distances4.3 penetration depth and energy streamlines in near-field radiative energy transfer; 4.4 effect of spatial dispersion on near-field heat transfer; 4.5 near-field heat transfer between metamaterials; 4.6 nanoscale radiation in thin films; 4.7 conclusions; references; 5.1 near-field heat transfer between two spheres; 5.2 near-field heat transfer between nanoparticles; 5.3 near-field radiative transfer between a particle and plane surface; 5.4 near-field heat transfer between two cylindrical objects
  • 5.5 near-field heat transfer between nanostructures5.6 concluding remarks; references; 6.1 plate-plate configuration; 6.2 tip-plate configuration; 6.3 sphere-plate configuration; 6.4 near-field measurements in nanostructures; 6.5 concluding remarks; references; 7.1 near-field thermophotovoltaics; 7.2 near-field thermal rectification; 7.3 thermal switch; 7.4 near-field thermal transistor; 7.5 near-field thermal memory; 7.6 heat-assisted magnetic recording and radiative cooling; 7.7 near-field imaging and fabrication; 7.8 conclusion; references; a; b; c; d; e; f; g; h; i; k; l; m; n; p; q; r; s
  • TU; V; W; Z; 1.1.1 Conduction; 1.1.2 Convection; 1.1.3 Radiation; 1.2.1 Entropy Analysis Applied to Special Cases; 1.3.1 Maxwell's Equations; 1.3.2 Solution of Maxwell's Equations; 1.3.3 Fluctuation Dissipation Theorem; 1.3.4 Density of States in Near-Field Radiation; 2.1.1 Dyadic Green's Function for Multilayered Media; 2.1.2 Emitting Film; 2.1.3 Semi-infinite Half Space; 2.5.1 Near-Field Heat Transfer; 3.1.1 Drude Model; 3.1.2 Lorentz Model; 3.1.3 Effective Medium Theory; 3.1.4 Phase Change Materials; 3.1.5 Hyperbolic Metamaterials; 3.2.1 Evanescent Waves; 3.2.2 Surface Polaritons

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