Henri Benisty received his PhD in electrochemistry in 1989 in Paris, working on the photonics of semiconductor integrated optics devices and LEDs enhanced with microcavities and two-dimensional photonic crystals, with the aim to improve either light confinement or light extraction. He is the co-founder of the French startup Genewave (now merged with Finnish Mobidiag), which works on fluorescence biochips. He has contributed to studies of sensors featuring a resonant waveguide grating response in various contexts and was instrumental to introducing the the idea of plasmonic losses within the recently introduced topic of parity-time symmetry in optics. Jean-Jacques Greffet is an alumnus of the Ecole Normale Suprieure de Paris-Saclay. He received his PhD in solid state physics in 1988 from Universit Paris-Sud working in light scattering by rough surfaces. Between 1994 and 2005, he worked on the theory of image formation in near-field optics. Since 1998, he has made a number of seminal contributions to the field of thermal radiation at the nanoscale including the demonstration of coherent thermal sources and the prediction and measurement of giant radiative heat transfer at the nanoscale due to surface phonon polaritons. Since 2000, he has contributed to the field of quantum plasmonics and light emission with nanoantennas and metasurfaces. Philippe Lalanne is an alumnus of the Ecole Normale Suprieure de St Cloud. Currently, he is a CNRS researcher working at Bordeaux University. He is an expert in nanoscale electrodynamics, with an emphasis on modelling and theory. His current research is devoted to understanding how light interacts with subwavelength structures to demonstrate novel optical functionalities. He has launched new modal theories and has pioneered the development of large-NA metalenses with high-index nanostructures in the 1990s. Part I – Basics of Electromagnetic Optics; 1 Basics of Electrodynamics of Continuous Media; 2 Radiation; 3 Electrodynamics in Material Media: Constitutive Relations; 4 Propagation; 5 Reflection and Refraction at an Interface; 6 Guided Modes; 7 Basics of Resonators and Cavities; Part II – Optical Properties of Confined Electrons; 8 Semiconductors and Quantum Wells; 9 More Conned Electrons : Quantum Dots and Quantum Wires; Part III – Advanced Concepts in Nanophotonics; 10 Fundamental Concepts of Near-Field Optics; 11 Introduction to Super-Resolution Optical Imaging; 12 Scattering. Green Tensor and Local Density of Electromagnetic States; Part IV – Plasmonics; 13 Propagating Surface Plasmons; 14 Localized Surface Plasmons; Part V – Articial Media: Photonics Crystals and Meta-Materials; 15 Propagation in Periodic Media (I) : Bloch Modes and Homogenization; 16 Propagation in Periodic Media (II): Photonic Crystals; 17 Periodic Waveguide; 18 Metamaterials and Metasurfaces; Part VI – Confined Photons: Nanoantennas, Microcavities and Optoelectronic Devices; 19 Controlling Light-Matter Interaction at the Nanoscale with Cavities and Nanoantennas; 20 From Nanophotonics to Devices; Part VII – Fluctuational Electrodynamics; 21 Fluctuational Electrodynamics

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Introduction to Nanophotonics (Oxford Graduate Texts)
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