LEADER 04815nam  2201225z- 450 
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100   $a20202105d2020      |y         0
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135   $aurmn|---annan
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200 00$aNanostructured Light-Emitters
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2020
215   $a1 online resource (208 p.)
311 08$a3-03936-904-0 
311 08$a3-03936-905-9 
330   $aSignificant progress has been made in nanophotonics and the use of nanostructured materials for optoelectronic devices, including light-emitting diodes (LEDs) and laser diodes, which have recently attracted considerable attention due to their unique geometry. Nanostructures in small dimensions, comprising nanowires, nanotubes, and nanoparticles, etc,. can be perfectly integrated into a variety of technological platforms, offering novel physical and chemical properties for high-performance, light-emitting devices. This Special Issue aims to present the most recent advances in the field of nanophotonics, which focuses on LEDs and laser diodes. We invite contributions of original research articles, as well as review articles that are aligned to the following topics that include, but are not limited to, thetheoretical calculation, synthesis, characterization, and application of such novel nanostructures for light-emitting devices. The application of nanostructured light-emitters in general lighting, imaging, and displays is also highly encouraged.
606   $aHistory of engineering and technology$2bicssc
610   $aAlN
610   $ablue organic light emitting diodes
610   $aBrewster mode
610   $acompound semiconductor
610   $acore-shell structure
610   $acurrent distribution
610   $adistributed Bragg reflectors
610   $aencapsulation
610   $aepsilon-near-zero
610   $aflip-chip LED
610   $aGaN
610   $aGaN nanowires
610   $aGaN-based lasers
610   $agratings
610   $ahexagonal arrangement
610   $ahigh-power
610   $ahole transport layer
610   $ahole-pattern
610   $ahost-dopant
610   $aIII-nitride thin film
610   $aIII-Nitrides
610   $aInGaN/GaN light-emitting diode
610   $alight extraction efficiency
610   $alight-emitting diode (LED)
610   $alinewidth
610   $aLiquid phase deposition method
610   $alocalized surface plasmon
610   $aluminescence
610   $aluminescence intensity
610   $amicro-scale light emitting diode
610   $amolecular beam epitaxy
610   $amonoclinic
610   $an/a
610   $ananoparticles
610   $ananostructure
610   $ananostructured light-emitting devices
610   $ananostructured materials
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610   $anon-stoichiometric ZnxAgyInS1.5+x+0.5y nanocrystals
610   $aone-pot approach
610   $apatterning efficiency
610   $aPEDOT:PSS/MoO3-ammonia composite
610   $aperovskite light-emitting diodes
610   $aphotoluminescence properties
610   $aphoton emission efficiency
610   $aphotonic crystals
610   $aphotonic nanojet
610   $aphotonic nanojet array
610   $aphysical mechanism
610   $aplasmon mode
610   $aPt nanoparticles
610   $aPurcell effect
610   $asapphire substrate
610   $aself-assembly
610   $asilver nanoparticle
610   $asurface passivation
610   $asurface plasmon
610   $asurface/interface control
610   $asurface/interface modification
610   $asurface/interface properties
610   $atemplate-assisted self-assembly
610   $athree-step spin coating
610   $atransport materials
610   $atunable fluorescence emission
610   $aultraviolet
610   $aultraviolet (UV) emitter
610   $aultraviolet emitters
610   $avertical structure LED
610   $avisible light communication
610   $awideband absorber
610   $azinc oxide
610   $a?-Ga2O3
610   $a?LED displays
610   $a?LEDs
615  7$aHistory of engineering and technology
700   $aNguyen$b Hieu Pham Trung$4edt$01324781
702   $aNguyen$b Hieu Pham Trung$4oth
906   $aBOOK
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996   $aNanostructured Light-Emitters$93036290
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LEADER 06966oam  22005534a 450 
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200 10$aIntroduction to the Physics of Gyrotrons$fGregory S. Nusinovich ; foreword by Victor Granatstein and Richard Temkin
205   $a1st ed.
210   $cJohns Hopkins University Press$d2004
210  1$aBaltimore :$cJohns Hopkins University Press,$d2004.
210  4$dİ2004.
215   $a1 online resource (xvi, 335 p. :)$cill. ;
311 08$a0-8018-7921-3 
320   $aIncludes bibliographical references (p. 309-327) and index.
327   $aCover -- Half Title -- Title -- Dedication -- Copyright -- Contents -- Foreword -- Preface -- PART I INTRODUCTION TO GVRODEVICES -- Chapter 1 Introduction -- 1.1. Relativistic Dependence of Electron Cyclotron Frequency on Electron Energy -- 1.2. Quantum Interpretation of Induced Cyclotron Radiation -- 1.3. Autoresonance -- 1.4. Normal and Anomalous Doppler Effects -- 1.5. Electron Deceleration -- 1.6. Optimum Choice of Parameters -- 1.7. Problems and Solutions -- Chapter 2 Gyrotron Arrangement -- 2.1. Velocity Spread and Inhomogeneous Doppler Broadening Operation Near Cutoff -- 2.2. Electron Optics. Magnetron Injection Guns -- 2.3. Microwave Structures (Cavities and Waveguides) -- 2.4. Types of Gyrodevices -- 2.5. Magnets and Solenoids -- 2.6. Problems and Solutions -- PART II THEORY OF GvROTRON OsciLLATORS AND AMPLIFIERS -- Chapter 3 Linear Theory of the Gyromonotron -- 3.1. Transversely Homogeneous Model -- 3.2. Gyro-Averaged Equations of Electron Motion: General Approach -- 3.3. Excitation of Resonators: General Form -- 3.4. Self-Excitation Conditions -- 3.5. Mode Selection -- 3.6. Problems and Solutions -- Chapter 4 Nonlinear Theory of the Gyromonotron (Single-Mode Treatment) -- 4.1. Cold-Cavity Approximation -- 4.2. Self-Consistent Approach -- 4.3. Effect of Velocity Spread -- 4.4. Space-Charge Effects -- 4.5. Trade-Offs in the Gyrotron Design -- 4.6. Problems and Solutions -- Chapter 5 Mode Interaction in the Gyromonotron -- 5.1. Preliminary Remarks -- 5.2. Main Effects in the Mode Interaction -- 5.3. Start-up Scenario -- 5.4. Phase Locking in Multimode Gyrotrons -- 5.5. Problems and Solutions -- Chapter 6 Linear Theory of the Gyro-TWT -- 6.1. Introduction: Instability in Magnetoactive Plasma -- 6.2. Derivation of the Dispersion Equation for the Gyro-TWT -- 6.3. Small-Signal Gain in Single-Stage and !Vlultistage Devices -- 6.4. Bandwidth.
327   $a6.5. Stability -- Chapter 7 Nonlinear Theory of the Gyro-TWT -- 7.1. Self-Consistent Set of Equations. Energy Conservation Law. Low-Current Limit -- 7.2. Beam-Wave Interaction -- 7.3. Gain and Bandvvidth -- 7.4. Concluding Remarks -- 7.5. Problems and Solutions -- Chapter 8 Theory of Gyroklystrons -- 8.1. Introductory Remarks -- 8.2. General Formalism. Point-Gap Model -- 8.3. Gain, Bandwidth, and Efficiency -- 8.4. Two-Cavity Gyroklystron -- 8.5. Problems and Solutions -- Chapter 9 Fluctuations: Intrinsic and Extrinsic Noise -- 9.1. Radiation Linewidth, Sources of Noise -- 9.2. General Formalism -- 9.3. Intrinsic Noise Sources. Shot Noise -- 9.4. Extrinsic Noise -- 9.5. Phase Stability of Gyroamplifiers -- 9.6. Problems and Solutions -- PART III THE DEVELOPMENT OF GVRODEVICES -- Chapter 10 Gyrotron Oscillators for Controlled Fusion Experiments -- 10.1. Historical Introduction -- 10.2. Quasi-Optical Mode Converters -- 10.3. Output Windows -- 10.4. Depressed Collectors -- 10.5. Experimental Results -- Chapter 11 Gyroklystrons -- 11.1. Historical Introduction -- 11.2. Gyroklystrons for Radar Applications -- 11.3. Gyroklystrons for Charged Particle Accelerators -- Chapter 12 Gyro-Traveling-Wave Tubes -- 12.1. Historical Introduction -- 12.2. Large-Bandwidth Gyro-TWTs -- 12.3. High-Gain Gyro-TWTs -- Chapter 13 Other Types of Gyrodevices -- 13.1. Gyro-Backward-Wave Oscillator -- 13.2. Gyrotwystron -- 13.3. Quasi-Optical Gyrotron -- 13.4. Cyclotron Auto-Resonance Maser (CARM) -- 13.5. Cyclotron Maser Based on the Anomalous Doppler Effect -- 13.6. Large-Orbit Gyrotron -- 13.7. Peniotron, Gyropeniotron, and Autoresonant Peniotron -- 13.8. Problems and Solutions -- Summary -- Appendix 1: Derivation of Gyro-Averaged Equations -- Appendix 2: Wave Excitation by Electron Beams in Waveguides.
327   $aAppendix 3: Derivation of the Self-Consistent Set of Equations for the Gyro-TWT -- References -- Index.
330   $aAs unique sources of coherent high-power, microwave, and millimeter-wave radiation, gyrotrons are an essential part of the hunt for controlled fusion. Presently, gyrotrons are actively used for electron cyclotron resonance plasma heating and current drive in various controlled fusion reactors. These sources have been under development in many countries for more than forty years. In spite of their widespread use, however, there is as yet no single book to introduce non-specialists to this vital field.Now Gregory S. Nusinovich, an early pioneer of the gyrotron and widely regarded today as the world's leading authority on the subject, explains the fundamental physical principles upon which gyrotrons and related devices operate. Nusinovich first sets forth some "rules of thumb" that allow readers to understand gyrotron operation in simple terms. He then explores the fundamentals of the general theory of gyrotrons and offers an overview of the various types of gyro-devices, including gyromonotrons, gyroklystrons, gyro-traveling-wave tubes, and gyrotwystrons. He explains not only the theory, linear and nonlinear, but also the practical challenges that users of such devices face. This book will be of interest to undergraduate and graduate students as well as to those who develop gyrotrons or who use them in various applications. It should also appeal to plasma physicists interested in charged-particle dynamics, as well as to applied physicists needing to know more about micro- and millimeter-wave technologies.
606   $aParticle dynamics
606   $aPlasma radiation
606   $aGyrotrons
615  0$aParticle dynamics.
615  0$aPlasma radiation.
615  0$aGyrotrons.
676   $a530.4/4
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996   $aIntroduction to the Physics of Gyrotrons$92618022
997   $aUNINA