| Description |
1 online resource (xv, 339 pages) : illustrations, color portraits |
| Series |
Particle acceleration and detection |
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Particle acceleration and detection.
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| Contents |
Note continued: 6.10. Coupling Impedance -- 6.10.1. General Form of the Transverse Impedance -- 6.10.2. Minimizing the Transverse Impedance in Induction Cell Designs -- 6.10.3. Measurement of the Transverse Impedacnce -- 6.11. High Average Power -- 6.12. Summary of Cell Design -- References -- 7. Electron Induction Linacs / Yu-Jiuan Chen -- 7.1. Introduction -- 7.2. Electron Sources -- 7.2.1. Cathodes -- 7.2.2. Electron Guns -- 7.3. Beam Dynamics in Induction Machines -- 7.3.1. Basic Force Equation -- 7.3.2. Coordinate Description of a Beam -- 7.3.3. Focusing in a Solenoidal Field -- 7.4. Envelope Equations -- 7.4.1. Lee-Cooper Envelope Equation -- 7.4.2. KV Envelope Equations -- 7.5. Corkscrew Motion -- 7.5.1. Corkscrew Amplitude -- 7.5.2. Tuning Curve Algorithm -- 7.6. Instabilities -- 7.6.1. Image Displacement Instability -- 7.6.2. Beam Breakup Instability (BBU) -- 7.7. Induction Linac Design Considerations -- 7.7.1. Optimal Focusing Strategy -- 7.8. Nonlinear Focusing to Suppress BBU -- 7.8.1. Motivation for Nonlinear Focusing Systems -- 7.8.2. Laser Generated Ion Channel -- 7.8.3. Phase Mix Damping of BBU -- References -- 8. Applications of Electron Linear Induction Accelerators / Yu-Jiuan Chen -- 8.1. Linear Induction Accelerators Built for Flash X-Ray Radiography -- 8.1.1. Induction Accelerators Built for Radiography -- 8.1.2. Beam Requirements -- 8.1.3. Target Issues -- 8.2. Free Electron Lasers Driven by LIAs -- 8.2.1. ELF Experiments on the ETA Accelerator -- 8.2.2. Short Wavelength Radiation Production Using the ATA Accelerator -- 8.2.3. Use of Induction Accelerators to Produce Millimeter Wavelength Power for Tokamak Heating -- 8.3. Two-Beam Accelerators -- 8.4. High Average Power Applications -- 8.5. Conclusion -- References -- 9. Ion Induction Accelerators / Kazuhiko Horioka |
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Note continued: 9.1. Ion Sources and Injectors -- 9.1.1. Physics of High Current-Density Ion Sources -- 9.1.2. Ion Sources -- 9.1.3. Example Injectors -- 9.2. Longitudinal Beam Dynamics -- 9.2.1. Fluid Equation Approach -- 9.2.2. "g-Factor" Descriptions of Ez -- 9.2.3. Rarefaction Waves -- 9.2.4. "Ear Fields" -- 9.2.5. Longitudinal Waves -- 9.2.6. Longitudinal Instability -- 9.2.7. Effects of Capacitance on Longitudinal Instability -- 9.3. Transverse Dynamics Issues -- References -- 10. Applications of Ion Induction Accelerators / Richard J. Briggs -- 10.1. Driver for Heavy Ion Fusion (HIF) -- 10.1.1. Requirements Set by Target Physics -- 10.1.2. Final Focus Limits -- 10.1.3. Accelerator Architectures for Inertial Fusion Energy -- 10.1.4. Induction Acceleration and Energy Loss Mechanisms -- 10.1.5. Scaling of the Focusing Systems -- 10.1.6. Accelerator Scaling with Charge-to-Mass Ratio -- 10.1.7. Multi-Beam Linac with Quadrupole Focusing -- 10.1.8. Modular Drivers -- 10.1.9. Recirculator -- 10.1.10. Beam Manipulations -- 10.2. Other Applications of Ion Induction Accelerators -- 10.2.1. High Energy Density Physics, and Warm Dense Matter Physics -- 10.2.2. Neutron Spallation Source -- References -- 11. Induction Synchrotron / Ken Takayama -- 11.1. Principle of Induction Synchrotron -- 11.1.1. Review of Phase Dynamics in an RF Synchrotron -- 11.1.2. Phase Dynamics in the Induction Synchrotron -- 11.2. Beam Handling -- 11.2.1. Beam Injection -- 11.2.2. Beam Stacking and Super-Bunch Formation -- 11.2.3. Transition Crossing -- 11.3. Induction Devices for an Induction Synchrotron -- 11.3.1. Equivalent Circuit Model -- 11.3.2. Induction Cell -- 11.3.3. Switching Power Supply (Power Modulator) -- 11.4. Proof of Principle Experiment -- 11.4.1. Beam-Cell Interaction: Beam Loading |
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Note continued: 11.4.2. Scenario of Proof of Principle Experiment -- 11.4.3. Induction Acceleration of an RF Bunch -- 11.4.4. Confinement by Induction Barrier Voltages -- 11.4.5. Induction Acceleration of a Trapped Barrier Bunch-Full Demonstration of the Induction Synchrotron -- 11.5. Perspective -- References -- 12. Applications of Induction Synchrotrons / Ken Takayama -- 12.1. Typical Accelerator Complex Capable of Employing the Induction Synchrotron Scheme -- 12.2. Hybrid Synchrotrons -- 12.2.1. Quasi-adiabatic Focusing-Free Transition Crossing -- 12.3. Super-Bunch Hadron Colliders -- 12.3.1. Introduction -- 12.3.2. Contrast of Coasting Beam, RF Bunch Collider, and Super-Bunch Colliders -- 12.3.3. Generation of the Super-Bunch -- 12.3.4. Luminosity -- 12.3.5. Beam-Beam Effects and Crossing Geometry -- 12.3.6. Typical Super-Bunch Collider's Parameters -- 12.3.7. Beam Physics Issues for the Super-Bunch Hadron Collider -- 12.4. All-Ion Accelerator-An Injector-Free Induction Synchrotron -- 12.4.1. Introduction -- 12.4.2. Concept -- 12.4.3. Digital Acceleration and Switching Frequency -- 12.4.4. Longitudinal Confinement -- 12.4.5. Stacking and Beam Handling Through the Acceleration -- 12.4.6. Transverse Focusing -- 12.4.7. Space Charge Limited Ion-Beam Intensity -- 12.4.8. Vacuum -- 12.4.9. Ion Source and Injector -- 12.4.10. Summary -- References |
| Summary |
A broad class of accelerators rests on the induction principle whereby the accelerating electrical fields are generated by time-varying magnetic fluxes. Particularly suitable for the transport of bright and high-intensity beams of electrons, protons or heavy ions in any geometry (linear or circular) the research and development of induction accelerators is a thriving subfield of accelerator physics. This text is the first comprehensive account of both the fundamentals and the state of the art about the modern conceptual design and implementation of such devices. Accordingly, the first part of |
| Bibliography |
Includes bibliographical references and index |
| Notes |
English |
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Print version record |
| Subject |
Betatrons.
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SCIENCE -- Physics -- Nuclear.
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Physique.
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Astronomie.
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Betatrons
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| Genre/Form |
Conference papers and proceedings
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| Form |
Electronic book
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| Author |
Takayama, Ken
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Briggs, Richard J
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| ISBN |
9783642139178 |
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3642139175 |
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