Light, Plasmonics and Particles: Nanophotonics
Editat de M. Pinar Menguc, Mathieu Francoeuren Limba Engleză Paperback – 12 mai 2023
In order to develop new devices, processes and applications, we need to advance our understanding of light-matter interactions. For this purpose, we need to have a firm grasp of electromagnetic wave phenomena, and absorption and scattering of waves by different size and shape geometrical objects. In addition, understanding of tunneling of waves based on electron and lattice vibrations and coupling with the thermal fluctuations to enhance near-field energy transfer mechanisms are required for the development of future energy harvesting devices and sensors.
- Reviews the fundamental science, available computational tools, experimental systems, and a wide range of applications of plasmonics
- Connects the cross-cutting science of the physics of electromagnetic light scattering by particles, plasmonics and phononic interactions at the electronic, molecular and lattice levels of materials
- Reviews applications of light-matter interactions of particles, aerosols, hydrosols and localized plasmonics
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Specificații
ISBN-13: 9780323999014
ISBN-10: 0323999018
Pagini: 616
Ilustrații: 220 illustrations (100 in full color)
Dimensiuni: 191 x 235 x 32 mm
Greutate: 1.04 kg
Editura: ELSEVIER SCIENCE
Seria Nanophotonics
ISBN-10: 0323999018
Pagini: 616
Ilustrații: 220 illustrations (100 in full color)
Dimensiuni: 191 x 235 x 32 mm
Greutate: 1.04 kg
Editura: ELSEVIER SCIENCE
Seria Nanophotonics
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Cuprins
1. Overview of light, plasmonics, and particles
2. Maxwell’s equations for single-scattering particles
3. Fluctuational electrodynamics and thermal emission
4. The Lorenz-Mie theory
5. Optical force categorizations in the generalized Lorenz-Mie theory
6. T-matrix method for particles of arbitrary shape and composition
7. Applications of Maxwell’s equations to light scattering by dielectric particles
8. Scattering by compact particles using surface integral equations
9. Discrete dipole approximation
10. Discrete dipole approximation with surface interaction
11. The thermal discrete dipole approximation and the discrete system Green’s function methods for computational near-field radiative heat transfer
12. Rational design and optical tuning of plasmonic nanoparticles
13. Particle characterization with laboratory nephelometers
14. Imaging aerosol particles with digital in-line holography
15. Polarimetric remote sensing of cometary particles
16. Optical properties of nonspherical, light-absorbing particles: Black carbon and mineral dust aerosols
17. Carbonaceous particles in flames and fires
18. Radiative cooling paints
19. Plasmonic nanofluids for solar thermal applications
20. Near-field energy harvesting
21. Nanoantennas
22. Near-field radiative transfer for biologically inspired structures
23. Biosensing based on plasmonic devices
24. Plasmon and phonon polaritons in planar van der Waals heterostructures
25. Spectrally selective filters and their applications
26. Concluding remarks and future directions
2. Maxwell’s equations for single-scattering particles
3. Fluctuational electrodynamics and thermal emission
4. The Lorenz-Mie theory
5. Optical force categorizations in the generalized Lorenz-Mie theory
6. T-matrix method for particles of arbitrary shape and composition
7. Applications of Maxwell’s equations to light scattering by dielectric particles
8. Scattering by compact particles using surface integral equations
9. Discrete dipole approximation
10. Discrete dipole approximation with surface interaction
11. The thermal discrete dipole approximation and the discrete system Green’s function methods for computational near-field radiative heat transfer
12. Rational design and optical tuning of plasmonic nanoparticles
13. Particle characterization with laboratory nephelometers
14. Imaging aerosol particles with digital in-line holography
15. Polarimetric remote sensing of cometary particles
16. Optical properties of nonspherical, light-absorbing particles: Black carbon and mineral dust aerosols
17. Carbonaceous particles in flames and fires
18. Radiative cooling paints
19. Plasmonic nanofluids for solar thermal applications
20. Near-field energy harvesting
21. Nanoantennas
22. Near-field radiative transfer for biologically inspired structures
23. Biosensing based on plasmonic devices
24. Plasmon and phonon polaritons in planar van der Waals heterostructures
25. Spectrally selective filters and their applications
26. Concluding remarks and future directions