Perspectives in Optics Research.

Intro -- PERSPECTIVES IN OPTICS RESEARCH -- PERSPECTIVES IN OPTICS RESEARCH -- CONTENTS -- PREFACE -- RECENT PROGRESSES OF MULTI-WAVELENGTH SEMICONDUCTOR LASER DIODES FOR OPTICAL INFORMATION STORAGE SYSTEMS -- ABSTRACT -- 1. INTRODUCTION -- 2. HYBRID-INTEGRATED TWO-WAVELENGTH LASER DIODES -- 2.1. Conventional Type Lasers -- 2.2. Holographic Pick-Up Module Type Lasers -- 2.3. Chip-to-Chip Bonding Type Lasers -- 3. MONOLITHIC-INTEGRATED TWO WAVELENGTH LASER DIODES -- 3.1. Visible and Infrared Bands Integrated Type Lasers -- 3.2. Green and Red Bands Integrated Type Lasers -- 4. CONCLUSION -- REFERENCES -- SOLITON PROPAGATION IN THREE-LEVEL ATOMIC SYSTEM UNDER DETUNED EXCITATION -- Abstract -- 1.Introduction -- 2.Model -- 3.SolitonintheThree-LevelMediumPumpedbyCW-field -- 4.SolitonVelocity -- Conclusion -- Acknowledgment -- References -- IN-LINE HOLOGRAM RECONSTRUCTION BY USING ITERATIVE ALGORITHMS -- ABSTRACT -- 1. INTRODUCTION -- 2. FORMULAS USED IN RECONSTRUCTION -- 3. DIFFERENCES BETWEEN THE YG AND GS ALGORITHMS -- 4. OBJECT RECONSTRUCTION FROM DOUBLE OR MULTI HOLOGRAMS -- 5. OBJECT RECONSTRUCTION FROM A HOLOGRAM SERIES -- 6. CONCLUSION -- ACKNOWLEDGMENTS -- REFERENCES -- PHOTOACOUSTIC SPECTROSCOPY OF NO2 AND SEVERAL APPLICATIONS -- ABSTRACT -- 1. INTRODUCTION -- 1.1. Optical Techniques for Gas Traces Detection -- 1.2. Nitrogen Dioxide Pollution -- 1.3. Spectroscopy of the NO2 Molecule -- 1.4. Advantages of Visible PA Spectroscopy -- 2. MATERIALS, COMPONENTS AND GAS HANDLING -- 3. PULSED PA EXPERIMENTS -- 3.1. Theory -- 3.2. Data Processing: High Resolution FFT [21] -- 3.3. Experimental -- 3.3.1. Excitation by a Tunable Dye Laser (430-470 nm) -- 3.3.2. Excitation by the Second Harmonic of a Nd:YAG Laser (532 nm) -- 4. RESONANT PA EXPERIMENTS -- 4.1. Simple and Cheap Acquisition System.

4.2. Excitation by a Mechanically Modulated Green Laser -- 4.3. Excitation by a High Repetition Pulsed Green Laser [30] -- 5. ONE-DIMENSIONAL PIPE RESONATORS -- 5.1. Acoustic Transmission Line Model -- 5.2. SF6 Multiphoton Absorption Cross Section Determination [35] -- 6. CONCLUSION -- ACKNOWLEDGMENTS -- REFERENCES -- CHEMICAL OXYGEN IODINE LASER: CURRENT DEVELOPMENT STATUS AND APPLICATIONS -- ABSTRACT -- 1.0. BACKGROUND -- 2.0. BASICS OF CHEMICAL-OXYGEN IODINE LASER -- 2.1. Gain -- 2.2. Power Output and Chemical Efficiency -- 2.3. Singlet Oxygen Transport Loss -- 2.4. Iodine Molecular Dissociation -- 2.5. Extraction Efficiency -- 2.6. Mixing Efficiency -- 3.0. CHEMICAL-OXYGEN IODINE LASER: SUB-SYSTEMS -- 3.1. Singlet Oxygen Generators -- 3.1.1. Bubbler SOG -- 3.1.2. Rotating Disc SOG -- 3.1.3. Jet Singlet Oxygen Generator -- 3.2. Resonators -- 3.2.1. Stable Resonators -- 3.2.2. Unstable Resonator -- 3.2.3. Other Resonator Geometries -- 3.3. Nozzles and Iodine Injection System -- 3.3.1. Computational Analysis of Chemical Laser Flow Fields -- 3.4. Supersonic Diffuser -- 3.5. Trap and Vacuum Pumps -- 4.0. COIL: RECENT TRENDS -- 4.1. COIL Efficiency and Compactness Issues -- 4.1.1. Different Iodine Injection Schemes -- 4.1.2. Atomic Iodine Generation Schemes /Hybrid Electri-COIL -- 4.1.2.1. Iodine Dissociation by Electrical Means -- 4.1.2.2. Bond Splitting of CF3I or CH3I by Electric/Photolytic Discharge -- 4.1.2.3 'I2' Atoms from Reaction between I2 Donors &amp -- Atomic Halogens -- 4.1.3. Utilizing Basic Deuterium Peroxide (BDP) -- 4.2. Advanced Generators for Excitation of Iodine -- 4.2.1. All Gas Iodine Lasers -- 4.2.2. Electric COIL /Discharge Oxy-Iodine Laser (DOIL) -- 4.2.3. Fullerene -Oxygen Iodine Laser (FOIL) -- 4.3. Deployable Systems: Development of Pressure Recovery System (PRS) -- 4.3.1. Zeolite Vacuum Absorption Bed.

4.3.2 Ejector Based Pressure Recovery -- 4.3.3. Advanced Nozzles for Efficient Pressure Recovery -- 5.0. COIL APPLICATIONS -- 5.1. Industrial Applications -- 5.1.1. Cutting /Welding -- 5.1.2. Rock Crushing / Drilling -- 5.1.3. Decontamination and Decommissioning Applications -- 5.1.4. Space Debris Removal -- 5.2. Defense Applications -- 5.2.1. Air Borne Laser (ABL) -- 5.2.2. Advanced Tactical Laser (ATL) -- 6. CONCLUSION -- REFERENCES -- CHALCONES: POSSIBLE NEW MATERIALS FOR THIRD-ORDER NONLINEAR OPTICS -- ABSTRACT -- INTRODUCTION -- EXPERIMENT -- RESULTS -- Second Order Hyperpolarizability -- Nonlinear Absorption -- Optical Limiting -- p-(N,N-dimethyl)Dibenzylideneacetone -- Doping Polymers -- Concentration Dependence of Nonlinearity -- Degenerate Four Wave Mixing -- CONCLUSION -- ACKNOWLEDGMENT -- REFERENCES -- OPTICAL SUPERLATTICES: WHERE PHOTONS BEHAVE LIKE ELECTRONS -- Abstract -- 1Introduction -- 2PorousSilicon-BasedOne-DimensionalSystems -- 3BlochOscillationsofLight -- 3.1TheOpticalSuperlattice -- 3.2SamplePreparationandOpticalWSLs -- 3.3Time-ResolvedTransmissionMeasurements -- 4ResonantZenerTunnelingofLight -- 4.1TheDouble-MinibandOpticalSuperlattice -- 4.2ResonantZenerTunnelinginTime-Domain -- 5Conclusion -- Acknowledgments -- References -- INDEX.

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