Electrodynamic Characteristics of Accelerating Cavities
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A01=B V Zverev
A01=N P Sobenin
Accelerating Structure
advanced accelerator design
Author_B V Zverev
Author_N P Sobenin
Beam Channel
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Coupling Aperture
Coupling Cells
coupling chains
Coupling Coefficient
Coupling Slots
Coupling Window
Cross Bars
Drift Tubes
Electric Field Parameter
electrodynamic characteristics
electromagnetic simulation
Electron Linacs
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Equivalent Circuit
Feeding Waveguide
Finite Difference Method
Grid Gap
Homogeneous Boundary Conditions
Inductive Iris
Iris Aperture
linear accelerator cavity modelling
linear accelerators
microwave devices
particle accelerator physics
perturbation measurement methods
Quadrupole Symmetry
radiofrequency engineering
Rectangular Waveguide
resonant mode analysis
Rf Cavities
RF Cavity
Rf Generator
Shunt Impedance
Wake Fields
Product details
- ISBN 9789069940038
- Weight: 666g
- Dimensions: 152 x 229mm
- Publication Date: 23 Jul 1999
- Publisher: Taylor & Francis Ltd
- Publication City/Country: GB
- Product Form: Hardback
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Now available for the first time in English translation, this important book contains extensive material relating to the electrodynamic characteristics of linear accelerators, and gives a good overview of the fundamentals of accelerating cavity design. The authors describe the experimental methods and measurement techniques essential in this area of research, and provide comprehensive data about the electrodynamic characteristics of resonant structures, which are widely used in charged particle accelerators and microwave devices. Single cavities and coupling chains, excited in electrical and magnetic modes, are described numerically and analyzed in detail. The book also provides a valuable description of the perturbation method, which is illustrated using a unique collection of data.
Sobenin, N P; Zverev, B V
