Buch, Englisch, 304 Seiten, Format (B × H): 188 mm x 263 mm, Gewicht: 719 g
ISBN: 978-1-119-38444-1
Verlag: Wiley
Explore the latest research avenues in the field of high-power microwave sources and metamaterials
A stand-alone follow-up to the highly successful High Power Microwave Sources and Technologies, the new High Power Microwave Sources and Technologies Using Metamaterials, demonstrates how metamaterials have impacted the field of high-power microwave sources and the new directions revealed by the latest research. It’s written by a distinguished team of researchers in the area who explore a new paradigm within which to consider the interaction of microwaves with material media.
Providing contributions from multiple institutions that discuss theoretical concepts as well as experimental results in slow wave structure design, this edited volume also discusses how traditional periodic structures used since the 1940s and 1950s can have properties that, until recently, were attributed to double negative metamaterial structures.
The book also includes:
- A thorough introduction to high power microwave oscillators and amplifiers, as well as how metamaterials can be introduced as slow wave structures and other components
- Comprehensive explorations of theoretical concepts in dispersion engineering for slow wave structure design, including multi-transmission line models and particle-in-cell code virtual prototyping models
- Practical discussions of experimental measurements in dispersion engineering for slow wave structure design
- In-depth examinations of passive and active components, as well as the temporal evolution of electromagnetic fields
High Power Microwave Sources and Technologies Using Metamaterials is a perfect resource for graduate students and researchers in the areas of nuclear and plasma sciences, microwaves, and antennas.
Autoren/Hrsg.
Fachgebiete
Weitere Infos & Material
Editor Biographies xi
List of Contributors xiii
Foreword xvii
Preface xix
1 Introduction and Overview of the Book 1
Rebecca Seviour
1.1 Introduction 1
1.2 Electromagnetic Materials 2
1.3 Effective-Media Theory 4
1.4 History of Effective Materials 4
1.4.1 Artificial Dielectrics 4
1.4.2 Artificial Magnetic Media 5
1.5 Double Negative Media 7
1.5.1 DNG Realization 9
1.6 Backward Wave Propagation 9
1.7 Dispersion 10
1.8 Parameter Retrieval 12
1.9 Loss 13
1.10 Summary 14
References 14
2 Multitransmission Line Model for Slow Wave Structures Interacting with Electron Beams and Multimode Synchronization 17
Ahmed F. Abdelshafy, Mohamed A.K. Othman, Alexander Figotin, and Filippo Capolino
2.1 Introduction 17
2.2 Transmission Lines: A Preview 18
2.2.1 Multiple Transmission Line Model 18
2.3 Modeling of Waveguide Propagation Using the Equivalent Transmission Line Model 20
2.3.1 Propagation in Uniform Waveguides 21
2.3.2 Propagation in Periodic Waveguides 22
2.3.3 Floquet’s Theorem 24
2.4 Pierce Theory and the Importance of Transmission Line Model 25
2.5 Generalized Pierce Model for Multimodal Slow Wave Structures 28
2.5.1 Multitransmission Line Formulation Without Electron Beam: “Cold SWS” 28
2.5.2 Multitransmission Line Interacting with an Electron Beam: “Hot SWS” 30
2.6 Periodic Slow-Wave Structure and Transfer Matrix Method 32
2.7 Multiple Degenerate Modes Synchronized with the Electron Beam 34
2.7.1 Multimode Degeneracy Condition 34
2.7.2 Degenerate Band Edge (DBE) 34
2.7.3 Super Synchronization 35
2.7.4 Complex Dispersion Characteristics of a Periodic MTL Interacting with an Electron Beam 38
2.8 Giant Amplification Associated to Multimode Synchronization 39
2.9 Low Starting Electron Beam Current in Multimode Synchronization
