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Publisher's Noteguaranteed by the publisher for quality, authenticity, or access to any online entitlements included with the product.Electromagnetic Composites Data, Principles, and ApplicationsThis fully revised engineering and scientific handbook offers complete coverage of electromagnetic modeling and explains the characterization of composite materials from the theoretical, computational, and experimental points of view. The book extends the von Hippel text to include data on additional non-conducting dielectrics; semiconducting, conducting, and magnetic materials; and composites composed of two or more molecularly distinct compounds that range in size from nanometers to centimeters. Electromagnetic Composites Handbook: Models, Measurement, and Characterization, Second Edition, simplifies the development of multifunctional material designs and includes tabulated data for more than 300 materials. This updated edition covers:Wave Equations and Electromagnetic Constitutive ParametersSources and Dispersion for Polarization and PermittivitySources and Dispersion of Magnetization and PermeabilityFundamental Observables for Material MeasurementComposites and Effective Medium TheoriesConducting-Dielectric and Magneto-Dielectric CompositesNumerical Models of CompositesElectromagnetic Measurement Systems Summary for RF - Millimeter WavelengthsResonant Techniques for Material CharacterizationTransmission Line, Free Space Focused Beam and TE10N Measurement DetailsMicron and Nano Scale Composites
Contents
IntroductionOutlineReferencesChapter 1. Introduction to Wave Equations and Electromagnetic Constitutive Parameters1.1 Maxwell's Equations and Field Sources1.2 Permittivity and Charge1.3 Permeability and Current1.4 Wave Equations for Homogeneous and Inhomogeneous Materials1.5 Homogeneous Propagation in Linear Media1.6 ConclusionReferencesChapter 2. Sources and Dispersion for Polarization and Permittivity (f)2.1 Sources of Permittivity, Resistivity, and Conductivity in Materials2.2 Modeling Material Complex Permittivity and Its Frequency Dependence2.3 Small Damping, 02.4 DC, Zero Frequency, and DC Scaled Permittivity2.5 Combined Models for Permittivity2.6 Coupling Permittivity and Permeability2.7 Additional Bound Charge Contributions to Permittivity and Frequency Dispersion2.8 Permittivity Variation with TemperatureReferencesChapter 3. Sources and Dispersion of Magnetization and Permeability (f)3.1 Sources of Permeability3.2 Frequency Dispersion in Magnetic Materials3.3 Susceptibility Models for Data Analysis3.4 An Overview of Micromagnetic Models3.5 Kramers-Kronig (KK) Relationships3.6 Temperature-Dependent PermeabilityReferencesChapter 4. Fundamental Observables for Material Measurement4.1 Introduction4.2 Scattering of Plane Waves from Homogeneous Planar Boundaries and Material Slabs4.3 Single Planar Slab of Material4.4 Scattering: Cascade Matrix Method for Multi-Boundary Material Analysis4.5 Scattering from a Shunt Planar Impedance Sheet4.6 Transmission and Reflection from Anisotropic Laminates4.7 A Numerical Anisotropic Material Example4.8 ConclusionReferencesChapter 5. Composites and Effective Medium Theories5.1 Introduction5.2 EMT Development Timeline5.3 Limitations and Derivation of EMTs5.4 Scattering Functions for Spheres5.5 Scattering and EMT of Large-Aspect Ratio Particle Geometries5.6 Layered Inclusions5.7 Model Choices: Importance of Conduction and Particulate InteractionReferencesChapter 6. Conducting-Dielectric and Magneto-Dielectric Composites6.1 Introduction6.2 Percolation, Dimensionality, Depolarization, and Frequency Dispersion in Semiconducting, Conducting-Dielectric Composites6.3 Magnetic Effective MediaReferencesChapter 7. Numerical Models of Composites7.1 Method of Moment Modeling and Laminated Composites7.2 Finite Difference Time Domain Simulations7.3 Comments for Chapters 5 to 7ReferencesChapter 8. Electromagnetic Measurement Systems Summary for RF-Millimeter Wavelengths8.1 An Introduction to Wideband Material Metrology8.2 Error Correction, Calibration, and Causality8.3 Historical: Von Hippel and the Slotted Line8.4 Summary of Measurement Techniques8.5 Nonresonant Techniques: General Transmission Line Measurement Guidelines and Procedures8.6 Cylindrical Waveguide8.7 Coaxial Lines8.8 Stripline Measurements8.9 Focused Beam Free Space System8.10 Focused Beam Technical Description8.11 Calibration, Measurements, and DiscussionReferencesChapter 9. Resonant Techniques for Material Characterization9.1 Resonant Cavities9.2 Overview of the TE10p Measurement Technique9.3 Parallel Plate Stripline (TEM) Cavity9.4 Closed Reflection Cavity9.5 Open Cavity: Fabry-Perot ResonatorReferencesChapter 10. Transmission Line, Free Space Focused Beam and TE10N Measurement Details10.1 Constitutive Parameter Solutions in Coaxial Transmission Line, Rectangular Waveguide, and Free Space10.2 Extreme Elevated Temperature Reflection Measurements10.3 Free Space Focused Beam Characterization of Materials10.4 TE10N Transmission CavityReferencesChapter 11. Micrometer and Nanoscale Composites11.1 Applications and Impetus for Nano Magnetic Composites11.2 Case Study 1: NiZn and MnZn Ferrites11.3 Case Study 2: Nano Magnetic Composites11.4 Case Study 3: Multiscale EMT (Nano to Macro) for Artificial Dielectrics11.5 ConclusionsReferencesChapter 12. Measured Data of Materials and Composites12.1 Solid Ceramic versus Frequency12.2 Solid Ceramic versus Temperature12.3 Ceramic Fiber versus Temperature12.4 Two-Phase Ferrite-Polymer Composites and Three-Phase Ferrite-Fe-Polymer Composites12.5 Composites Demonstrating Percolation12.6 Solid Semiconductors versus Frequency12.7 Honeycomb and Foams versus Frequency12.8 Polymers versus Frequency12.9 R-Cards versus Frequency12.10 Micrometer and Nanometer Magnetite Magnetic Composites versus Frequency12.11 Iron-Polymer Composites versus Frequency12.12 Ceramic Polymer Fiber versus Frequency12.13 Dense Ferrites versus Frequency12.14 Fiber-Polymer Composites versus FrequencyIndexNER(01): WOW
