Near-Field Radiative Heat Transfer across Nanometer Vacuum Gaps Fundamentals and Applications Micro and Nano Technologies Series
Auteur : Basu Soumyadipta
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 investigates near-field heat transfer between different materials and geometries highlighting interplay between optics, material thermophysical properties and electromagnetism. The book also highlights the application of near-field thermal radiation in the field of power generation, imaging, and thermal systems as an analog of electronic devices.
Chapter 1. Introduction and Fundamental ConceptsChapter 2. Numerical Methods in Near-field Heat TransferChapter 3. Surface Waves and Dielectric FunctionChapter 4. Near-field Heat Transfer in Parallel MediaChapter 5. Near-field Heat Transfer in Non-Parallel Media and NanostructuresChapter 6. Experiments in Near-field Radiative Heat TransferChapter 7. Applications of Near-field RadiationChapter 8. Concluding Remarks
Academics and industry researchers in the field of near-field radiative heat transfer. Graduate students in physics, optics, electrical engineering and mechanical engineering.
- Brings together research in near-field radiative heat transfer in a focused and comprehensive manner, allowing those new to the topic to gain a thorough understanding of the science and how it can be used
- Offers focused coverage of heat transfer in near-field radiation, which other books do not
- Outlines the interplay between optics, electromagnetics, basic thermodynamics, and thermophysical properties of materials during near-field heat transfer
Date de parution : 06-2016
Ouvrage de 476 p.
19x23.4 cm
Thèmes de Near-Field Radiative Heat Transfer across Nanometer... :
Mots-clés :
Bloch; Bulk polariton; Cylinder; Dielectric function; Dipole; Drude model; Effective medium theory; Energy density; Entropy; Evanescent waves; Experiments; Finite difference time domain; Fluctuating source; Fluctuational electrodynamics; Gratings; Heat transfer; Hyperbolic metamaterials; Imaging; Lorentz model; Magnetic recording; Maxwell's equations; Metamaterials; Nanoholes; Nanowires; Near-field cooling; Near-field radiation; Near-field; Numerical solution; Parallel plate; Penetration depth; Photonic crystals; Plasmons; Polaritons; Radiation; RCWA; Scattering matrix; Silicon; Sphere; SThM; STM; Streamlines; Surface waves; Switch; Thermal discrete dipole; Thermal memory; Thermal rectification; Thermophotovoltaics; Thin films; Transistor; Weiner chaos