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Electron Beams and Microwave Vacuum Electronics (Wiley Series in Microwave and Optical Engineering)by Shulim E. Tsimring
Synopses & ReviewsPublisher Comments:The physics and theory underlying electron beams and microwave vacuum electronics
This book focuses on a fundamental feature of vacuum electronics: the strong interaction of the physics of electron beams and vacuum microwave electronics, including millimeterwave electronics. The author guides readers from the roots of classical vacuum electronics to the most recent achievements in the field, exploring both the physics and the theory underlying electron beams and devices of vacuum highfrequency electronics. Special attention is devoted to the physics and theory of relativistic beams and microwave devices. Readers gain a deep understanding of the topic as well as the theory and applications of specific devices. The book consists of two parts. Highlights of Part One, "Electron Beams," include:
Part Two, "Microwave Vacuum Electronics," features coverage of such topics as:
The author clearly states problems and then explores appropriate models, approximations, and derivations. This book, based on the author's own research and lectures, is recommended for students, researchers, and engineers working in such fields as electron beam technology, highfrequency vacuum devices for communications, radar, controlled fusion, charged particle accelerators, materials processing, and biomedicine. Book News Annotation:Tsimring (applied physics, Nizhny Novgorod State U., Russia) focuses on fundamental features of vacuum electronics, including the strong interaction of the physics of electron beams and vacuum electronics, including millimeterwave electronics. He explains the motion of charged particles in static fields, the theory of electronic lenses and electron beams with self fields and problems in the formulation and transport of intense electron beams. He then focuses on microwave vacuum electronics, explaining the physics and theory of the interaction of electron beams with electromagnetic fields in quasistationary systems such as diodes and klystrons, systems with continuous interactions such as traveling wave tubes, backward magnetrons and crossedfield amplifiers, and systems based on stimulated radiation of classical electron oscillations. He includes models, approximations and deviations and makes the text accessible to students as well as researchers and engineers in electronics, physics and biomedicine. Annotation ©2006 Book News, Inc., Portland, OR (booknews.com)
Synopsis:This book focuses on a fundamental feature of vacuum electronics: the strong interaction of the physics of electron beams and vacuum microwave electronics, including millimeterwave electronics. The author guides readers from the roots of classical vacuum electronics to the most recent achievements in the field. Special attention is devoted to the physics and theory of relativistic beams and microwave devices, as well as the theory and applications of specific devices.
About the AuthorSHULIM E. TSIMRING, PhD, DSc, is a consultant in the field of applied physics. Dr. Tsimring has taught at a number of universities, most recently as a professor at Nizhny Novgorod State University, Russia. Simultaneously, he was engaged in powerful highfrequency electronics research at the Institute of Applied Physics of the Russian Academy of Sciences in Nizhny Novgorod.
Table of ContentsPREFACE.
Introduction. I.1 Outline of the Book. I.2 List of Symbols. I.3 Electromagnetic Fields and Potentials. I.4 Principle of Least Action. Lagrangian. Generalized Momentum. Lagrangian Equations. I.5 Hamiltonian. Hamiltonian Equations. I.6 Liouville Theorem. I.7 Emittance. Brightness. PART I ELECTRON BEAMS. 1 Motion of Electrons in External Electric and Magnetic Static Fields. 1.1 Introduction. 1.2 Energy of a Charged Particle. 1.3 Potential–Velocity Relation (Static Fields). 1.4 Electrons in a Linear Electric Field e0E ¼ kx. 1.5 Motion of Electrons in Homogeneous Static Fields. 1.6 Motion of Electrons in Weakly Inhomogeneous Static Fields. 1.6.1 Small Variations in Electromagnetic Fields Acting on Moving Charged Particles. 1.7 Motion of Electrons in Fields with Axial and Plane Symmetry. Busch’s Theorem. 2 Electron Lenses. 2.1 Introduction. 2.2 Maupertuis’s Principle. ElectronOptical Refractive Index. Differential Equations of Trajectories. 2.3 Differential Equations of Trajectories in Axially Symmetric Fields. 2.4 Differential Equations of Paraxial Trajectories in Axially Symmetric Fields Without a Space Charge. 2.5 Formation of Images by Paraxial Trajectories. 2.6 Electrostatic Axially Symmetric Lenses. 2.7 Magnetic Axially Symmetric Lenses. 2.8 Aberrations of Axially Symmetric Lenses. 2.9 Comparison of Electrostatic and Magnetic Lenses. Transfer Matrix of Lenses . 2.10 Quadrupole lenses. 3 Electron Beams with Self Fields. 3.1 Introduction. 3.2 SelfConsistent Equations of SteadyState SpaceCharge Electron Beams. 3.3 Euler’s Form of a Motion Equation. Lagrange and Poincare´ Invariants of Laminar Flows. 3.4 Nonvortex Beams. Action Function. Planar Nonrelativistic Diode. Perveance. Child–Langmuir Formula. r and TModes of Electron Beams. 3.5 Solutions of SelfConsistent Equations for Curvilinear SpaceCharge Laminar Beams. Meltzer Flow. Planar Magnetron with an Inclined Magnetic Field. Dryden Flow. 4 Electron Guns. 4.1 Introduction. 4.2 Pierce’s Synthesis Method for Gun Design. 4.3 Internal Problems of Synthesis. Relativistic Planar Diode. Cylindrical and Spherical Diodes. 4.4 External Problems of Synthesis. Cauchy Problem. 4.5 Synthesis of Electrode Systems for TwoDimensional Curvilinear Beams with Translation Symmetry (Lomax–Kirstein Method). Magnetron Injection Gun. 4.6 Synthesis of Axially Symmetric Electrode Systems. 4.7 Electron Guns with Compressed Beams. Magnetron Injection Gun. 4.8 Explosive Emission Guns. 5 Transport of SpaceCharge Beams. 5.1 Introduction. 5.2 Unrippled Axially Symmetric Nonrelativistic Beams in a Uniform Magnetic field. 5.3 Unrippled Relativistic Beams in a Uniform External Magnetic Field.. 5.4 Cylindrical Beams in an Infinite Magnetic Field. 5.5 Centrifugal Electrostatic Focusing. 5.6 ParaxialRay Equations of Axially Symmetric Laminar Beams. 5.7 Axially Symmetric Paraxial Beams in a Uniform Magnetic Field with Arbitrary Shielding of a Cathode Magnetic Field. 5.8 Transport of SpaceCharge Beams in Spatial Periodic Fields. PART II MICROWAVE VACUUM ELECTRONICS. 6 Quasistationary Microwave Devices. 6.1 Introduction. 6.2 Currents in Electron Gaps. Total Current and the Shockley–Ramo Theorem. 6.3 Admittance of a Planar Electron Gap. Electron Gap as an Oscillator. Monotron. 6.4 Equation of Stationary Oscillations of a Resonance SelfExcited Circuit. 6.5 Effects of a SpaceCharge Field. Total Current Method. HighFrequency Diode in the rMode. Llewellyn–Peterson Equations. 7 Klystrons. 7.1 Introduction. 7.2 Velocity Modulation of an Electron beam. 7.3 Cinematic (Elementary) Theory of Bunching. 7.4 Interaction of a Bunched Current with a Catcher Field. Output Power of A TwoCavity Klystron. 7.5 Experimental Characteristics of a TwoResonator Amplifier and FrequencyMultiplier Klystrons. 7.6 SpaceCharge Waves in VelocityModulated Beams. 7.7 Multicavity and Multibeam Klystron Amplifiers. 7.8 Relativistic Klystrons. 7.9 Reflex Klystrons. 8 TravelingWave Tubes and BackwardWave Oscillators (OType Tubes). 8.1 Introduction. 8.2 Qualitative Mechanism of Bunching and Energy Output in a TWTO. 8.3 SlowWave Structures. 8.4 Elements of SWS Theory. 8.5 Linear Theory of a Nonrelativistic TWTO. Dispersion Equation, Gain, Effects of Nonsynchronism, Space Charge, and Loss in a SlowWave Structure. 8.6 Nonlinear Effects in a Nonrelativistic TWTO. Enhancement of TWTO Efficiency (Velocity Tapering, Depressed Collectors). 8.7 Basic Characteristics and Applications of Nonrelativistic TWTOs. 8.8 BackwardWave Oscillators. 8.9 Millimeter Nonrelativistic TWTOs, BWOs, and Orotrons. 8.10 Relativistic TWTOs and BWOs. 9 CrossedField Amplifiers and Oscillators (MType Tubes). 9.1 Introduction. 9.2 Elementary Theory of a Planar MTWT. 9.3 MTWT Amplification. 9.4 Mtype Injected Beam BackwardWave Oscillators (MWO, MCarcinotron). 9.5 Magnetrons. 9.6 Relativistic Magnetrons. 9.7 Magnetically Insulated Line Oscillators. 9.8 CrossedField Amplifiers. 10 Classical Electron Masers and Free Electron Lasers. 10.1 Introduction. 10.2 Spontaneous Radiation of Classical Electron Oscillators. 10.3 Stimulated Radiation of Excited Classical Electron Oscillators. 10.4 Examples of Electron Cyclotron Masers. 10.5 Resonators of Gyromonotrons (Free and Forced Oscillations). 10.6 Theory of a Gyromonotron. 10.7 Subrelativistic Gyrotrons. 10.8 Elements of Gyrotron Electron Optics. 10.9 Mode Interaction and Mode Selection in Gyrotrons. Output Power Systems. 10.10 Gyroklystrons. 10.11 GyroTravelingWave Tubes. 10.12 Applications of Gyrotrons. 10.13 Cyclotron Autoresonance Masers. 10.14 Free Electron Lasers. Appendixes. 1. Proof of the 3/2 Law for Nonrelativistic Diodes in the rMode. 2. Synthesis of Guns for MType TWTS and BWOS. 3. Magnetic Field in Axially Symmetric Systems. 4. Dispersion Characteristics of Interdigital and Comb Structures. 5. Electromagnetic Field in Planar Uniform SlowWave Structures. 6. Equations of Free Oscillations of Gyrotron Resonators. 7. Derivation of Eqs. (10.66) and (10.67). 8. Calculation of Fourier Coefficients in Gyrotron Equations. 9. Magnetic Systems of Gyrotrons. References. Index. What Our Readers Are SayingBe the first to add a comment for a chance to win!Product Details
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