Nano-optics : fundamentals, experimental methods, and applications / edited by Sabu Thomas [and more].
Contributor(s): Thomas, Sabu
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Material type: 
BookSeries: Micro and Nano Technologies Ser: Publisher: Amsterdam : Elsevier, 2020Description: 1 online resource.Content type: text Media type: computer Carrier type: online resourceISBN: 9780128183939; 0128183934.Subject(s): Nanophotonics | Nanostructured materials | Nanostructures | Nanophotonique | Nanomat�eriaux | Nanophotonics | Nanostructured materialsAdditional physical formats: Print version:: No titleDDC classification: 621.36 Online resources: ScienceDirect Includes index.
Intro -- Nano-Optics: Fundamentals, Experimental Methods, and Applications -- Copyright -- Contents -- Contributors -- About the Editors -- Chapter 1: From nature: Optics, nanotechnology, and nano-optics -- 1. Introduction -- 2. Nature and optics -- 3. Nanotechnology in nature -- 4. Presence of nano-optics in nature -- 4.1. Light manipulation -- 4.2. Antireflection -- 4.3. Light focusing -- 4.4. Chirality -- 5. Summary -- References -- Chapter 2: Nano-optics: Challenges, trends, and future -- 1. An outlook -- 1.1. A historical perspective -- 1.2. Photonics -- 1.3. Speed of light
1.4. Focal length of thin spherical lens and refractive index -- 1.5. Brewster's angle -- 1.6. Optical properties of nanoparticles -- 2. Challenges: Nano-optics bottleneck -- 3. Trends: Current scenario in nano-optics -- 4. The future: A world of possibilities -- 5. Conclusion -- References -- Chapter 3: Nano-optics for healthcare applications -- 1. Introduction -- 2. Nano-optics for bio imaging -- 3. Nano-optics for biosensing -- 4. Nano-optics for cancer therapy -- 5. Conclusion -- References -- Chapter 4: Laser, nanoparticles, and optics -- 1. Laser-Introduction
1.1. Laser principle and properties -- 1.2. Applications of laser in nanotechnology -- 1.3. Applications of nanotechnology in laser devices -- 1.4. Laser-produced nanoparticles -- 1.4.1. Synthesis approach -- 2. Random lasing -- 2.1. Coherent and incoherent random lasers -- 2.2. Fabrication of the random media: Importance of nanostructured materials -- 2.3. Plasmonically enhanced random laser to spaser -- 2.4. Directionality in random lasers -- 3. Applications of random lasers -- References -- Chapter 5: Introduction to quantum plasmonic sensing -- 1. Introduction -- 2. Plasmonic sensing
2.1. Surface plasmon resonance sensing -- Spectral interrogation -- 2.2. Localized surface plasmon resonance sensing -- 2.3. Other plasmonic sensors -- 2.4. Intensity- and phase-sensitive sensing -- 3. Quantum sensing -- 3.1. Shot-noise limit -- 3.2. Subshot-noise sensing -- 3.3. Single-mode schemes -- 3.4. Two-mode schemes -- 4. Quantum plasmonic sensing -- 4.1. Quantum sensing with metallic nanoparticles -- 4.1.1. Refractive index sensing with two-mode squeezed vacuum states -- 4.1.2. Ultrasound sensing with two-mode squeezed displaced states
4.2. Quantum sensing with metallic film-prism setups -- 4.2.1. Refractive index sensing with two-mode squeezed displaced states -- Comparison among different state inputs -- 4.2.2. Refractive index sensing with photon number states -- 4.3. Quantum sensing with metallic nanowires -- 5. Conclusion -- References -- Chapter 6: Nanobiophotonics and fluorescence nanoscopy in 2020 -- 1. Introduction -- 1.1. Electrons, photons, and plasmons -- 1.2. Nanoparticles -- 2. Optical microscopy to nanoscopy -- 2.1. Optical resolution: A historical perspective -- 2.2. Optical nanoscopy
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