Principles of Charged Particle Acceleration (eBook, 2013) [University of Washington Libraries]
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Principles of Charged Particle Acceleration

Principles of Charged Particle Acceleration

Author: Stanley Humphries
Publisher: Newburyport : Dover Publications, 2013.
Edition/Format:   eBook : Document : EnglishView all editions and formats
Summary:
""Principles of Charged Particle Acceleration has been one of my primary reference books for my research in the generation, focusing, and application of high power electron and ion beams using pulsed power accelerators. . . . It remains a classic reference that is both useful and accessible.""-Thomas A. Mehlhorn, Superintendent, Plasma Physics Division, Naval Research Laboratory""The book succeeds in explaining the  Read more...
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Details

Genre/Form: Electronic books
Material Type: Document, Internet resource
Document Type: Internet Resource, Computer File
All Authors / Contributors: Stanley Humphries
ISBN: 0486320634 9780486320632
Language Note: English.
OCLC Number: 1162595955
Notes: Description based upon print version of record.
9.14. Diagnostics for Pulsed Voltages and Currents
Description: 1 online resource (1132 p.)
Contents: Cover; Title Page; Copyright Page; Dedication; Preface to the Dover Edition; Preface; Contents; 1. Introduction; 2.1. Charged Particle Properties; 2.2. Newton's Laws of Motion; 2.3. Kinetic Energy; 2.4. Galilean Transformations; 2.5. Postulates of Relativity; 2.6. Time Dilation; 2.7. Lorentz Contraction; 2.8. Lorentz Transformations; 2.9. Relativistic Formulas; 2.10. Nonrelativistic Approximation for Transverse Motion; 2. Particle Dynamics; 3.1. Forces between Charges and Currents; 3.4. Electrostatic and Vector Potentials; 3.5. Inductive Voltage and Displacement Current 3.6. Relativistic Particle Motion in Cylindrical Coordinates3.7. Motion of Charged Particles in a Uniform Magnetic Field; 3. Electric and Magnetic Forces; 4.1. Static Field Equations with No Sources; 4.2. Numerical Solutions to the Laplace Equation; 4.3. Analog Methods to Solve the Laplace Equation; 4.4. Electrostatic Quadrupole Field; 4.5. Static Electric Fields with Space Charge; 4.6. Magnetic Fields in Simple Geometries; 4.7. Magnetic Potentials; 4. Steady-State Electric and Magnetic Fields; 5.1. Dielectrics; 5.2. Boundary Conditions at Dielectric Surfaces; 5.3. Ferromagnetic Materials 5.4. Static Hysteresis Curve for Ferromagnetic Materials5.5. Magnetic Poles; 5.6. Energy Density of Electric and Magnetic Fields; 5.7. Magnetic Circuits; 5.8. Permanent Magnet Circuits; 5. Modification of Electric and Magnetic Fields by Materials; 6.1. Transverse Beam Control; 6.2. Paraxial Approximation for Electric and Magnetic Fields; 6.3. Focusing Properties of Linear Fields; 6.4. Lens Properties; 6.5. Electrostatic Aperture Lens; 6.6. Electrostatic Immersion Lens; 6.7. Solenoidal Magnetic Lens; 6.8. Magnetic Sector Lens; 6.9. Edge Focusing; 6.10. Magnetic Quadrupole Lens 6. Electric and Magnetic Field Lenses7.1. Transverse Orbits in a Continuous Linear Focusing Force; 7.2. Acceptance and v of a Focusing Channel; 7.3. Betatron Oscillations; 7.4. Azimuthal Motion of Particles in Cylindrical Beams; 7.5. The Paraxial Ray Equation; 7.6. Numerical Solutions of Particle Orbits; 7. Calculation of Particle Orbits in Focusing Fields; 8.1. Transfer Matrix of the Quadrupole Lens; 8.2. Transfer Matrices for Common Optical Elements; 8.3. Combining Optical Elements; 8.4. Quadrupole Doublet and Triplet Lenses; 8.5. Focusing in a Thin-Lens Array 8.6. Raising a Matrix to a Power8.7. Quadrupole Focusing Channels; 8. Transfer Matrices and Periodic Focusing Systems; 9.1. Resistors, Capacitors, and Inductors; 9.2. High-Voltage Supplies; 9.3. Insulation; 9.4. Van de Graaff Accelerator; 9.5. Vacuum Breakdown; 9.6. LRC Circuits; 9.7. Impulse Generators; 9.8. Transmission Line Equations in the Time Domain; 9.9. Transmission Lines as Pulsed Power Modulators; 9.10. Series Transmission Line Circuits; 9.11. Pulse-Forming Networks; 9.12. Pulsed Power Compression; 9.13. Pulsed Power Switching by Saturable Core Inductors

Abstract:

""Principles of Charged Particle Acceleration has been one of my primary reference books for my research in the generation, focusing, and application of high power electron and ion beams using pulsed power accelerators. . . . It remains a classic reference that is both useful and accessible.""-Thomas A. Mehlhorn, Superintendent, Plasma Physics Division, Naval Research Laboratory""The book succeeds in explaining the key accelerator concepts clearly and starting from basic physical principles. . . . I recommend this book to both novices and experts.""-Richard J. Adler, Senior Principal Scientist.
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