(Ebook PDF) Nanostructured Nonlinear Optical Materials Formation and Characterization Micro and Nano Technologies 1st edition by Rashid Ganeev ISBN 9780128143049 0128143045 full chapters

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ISBN 10: 0128143045

ISBN 13: 9780128143049

Author: Rashid A. Ganeev

Nanostructured Nonlinear Optical Materials: Formation and Fabrication covers the analysis of the formation, characterization and optical nonlinearities of various nanostructures using different methods. It addresses many areas of research in the field, including the modification of the surfaces of materials for the formation of various nanostructures, transmission electron microscopy and time-of-flight mass spectroscopy studies of ablated bulk and nanoparticle targets, the low-order nonlinearities of metal and semiconductor nanoparticles, the nonlinear refraction and nonlinear absorption of carbon-contained nanoparticles, and low- and high-order harmonic generation in nanoparticle-contained plasmas, amongst other topics.

Table of Contents:

• Introduction
• Chapter 1: Periodic nanoripples formation on the semiconductors possessing different bandgaps
• Abstract
• 1.1. Nanoripple Formation on Different Bandgap Semiconductor Surfaces Using Femtosecond Pulses
• 1.2. Nanosecond Laser-Induced Periodic Surface Structures Formation on Wide Bandgap Semiconductors Using Nanosecond Ultraviolet Pulses
• 1.3. Fabrication of Two-Dimensional Periodic Nanostructures by Two-Beam Interference of Femtosecond Pulses
• 1.4. Extended Homogeneous Nanoripple Formation During Interaction of High-Intensity Few-cycle Pulses With a Moving Silicon Wafer
• 1.5. Concluding Comments
• Chapter 2: Formation of nanoparticles, nanoholes, nanoripples, and nanowires using different conditions of laser–matter interaction
• Abstract
• 2.1. Formation of Different Periodic Nanostructures on Semiconductors
• 2.2. Nanoparticle Formation During Laser Ablation of Metals at Different Pressures of Surrounding Noble Gases
• 2.3. Deposition of Nanoparticles During Laser Ablation of Nanoparticle-Containing Targets
• 2.4. Application of Ion Implantation for Synthesis of Copper Nanoparticles in a Zinc Oxide Matrix for Obtaining New Nonlinear Optical Materials
• 2.5. Pulsed Laser Deposition of Metal Films and Nanoparticles in Vacuum Using Subnanosecond Laser Pulses
• 2.6. Concluding Comments
• Chapter 3: Methods of nanostructured materials characterization
• Abstract
• 3.1. Morphology of Laser-Produced Carbon Nanoparticle Plasmas
• 3.2. Synthesis and Photoluminescence Properties of Silver Nanowires
• 3.3. Optical Properties and Luminescence of Copper Nanoclusters in ZnO
• 3.4. Ion Synthesis and Analysis of the Optical Properties of the Gold Nanoparticles in an Al2O3 Matrix
• 3.5. Concluding Comments to Chapter 3
• Chapter 4: Low-order nonlinear optical properties of metal nanoparticles
• Abstract
• 4.1. Basic Principles of the Nonlinear Optical Characterization of Materials
• 4.2. Nonlinear Optical Properties of Copper Nanoparticles Implanted in Silicate Glass
• 4.3. Application of RZ-scan Technique for Analysis of the Nonlinear Refraction of Opaque Sapphire Doped With Ag, Cu, and Au Nanoparticles
• 4.4. Characterization of Optical and Nonlinear Optical Properties of Silver Nanoparticles Prepared by Laser Ablation in Various Liquids
• 4.5. Low-Order Nonlinear Optical Properties of Au, Pt, Pd, and Ru Nanoparticles
• 4.6. Concluding Comments
• Chapter 5: Nonlinear absorption and refraction in semiconductor and carbon-contained nanoparticles
• Abstract
• 5.1. Analysis of Nonlinear Refraction and Nonlinear Absorption of Semiconductor Nanoparticles Solutions Prepared by Laser Ablation
• 5.2. Low-Order Nonlinear Optical Properties of BaTiO3 and SrTiO3 Nanoparticles
• 5.3. Laser Ablation of GaAs in Liquids: Structural, Optical, and Nonlinear Optical Characterization of Colloidal Solutions
• 5.4. Variations of Nonlinear Optical Characteristics of C60 Thin Films
• 5.5. Concluding Comments
• Chapter 6: Frequency conversion in fullerenes
• Abstract
• 6.1. High-Order Harmonic Generation (HHG) From Fullerene by Means of the Plasma Harmonic Method
• 6.2. Peculiarities of HHG From C60-Rich Plasma
• 6.3. Influence of C60 Morphology on the Spectrum and HHG Enhancement in Fullerene-Containing Plasma
• 6.4. HHG in Fullerenes Using Few- and Multi-Cycle Pulses of Different Wavelengths
• 6.5. Endohedral Fullerenes: A Way to Control Resonant HHG
• 6.6. Concluding Comments
• Chapter 7: High-order harmonic generation in carbon-containing nanoparticles
• Abstract
• 7.1. High-Order Harmonic Generation in Carbon Nanotube-Containing Plasma Plumes
• 7.2. Graphene-Containing Plasma: A Medium for the Coherent Extreme Ultraviolet Light Generation
• 7.3. Graphene in Strong Laser Field: Experiment and Theory
• 7.4. High-Order Harmonic Generation of Ultrashort Pulses in Clustered Media
• 7.5. Concluding Comments
• Chapter 8: Harmonic generation using metal and semiconductor nanoparticles
• Abstract
• 8.1. High-Order Harmonic Generation in Inorganic Nanoparticle-Containing Laser-Produced Plasmas
• 8.2. Comparison of High-Order Harmonic Generation from Various Cluster- and Ion-Containing Laser Plasmas
• 8.3. Comparative Studies of the High-Order Harmonic Generation from Different Metal Nanoparticles
• 8.4. High-Order Harmonic Generation in a Plasma Plume of In Situ Laser-Produced Silver Nanoparticles
• 8.5. Concluding Comments
• Chapter 9: Peculiarities of high-order harmonic generation in nanoparticles
• Abstract
• 9.1. Ablation of Nanoparticles and Efficient Harmonic Generation Using a 1 kHz Laser
• 9.2. Peculiarities of HHG in Plasmas From Nanoparticle Targets at 1-kHz Repetition Rate
• 9.3. Influence of a Few-Atomic Silver Molecules on the High-Order Harmonic Generation in the Laser-Produced Plasmas
• 9.4. Resonance-Enhanced Harmonic Generation in Nanoparticle-Containing Plasmas
• 9.5. Concluding Comments

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Rashid Ganeev,Nanostructured Nonlinear,Optical Materials