【内容简介】
从理论、计算和实验的角度进行材料的表征,涉及非导电介质、半导体材料、导电材料、磁性材料和复合材料等,共提供了300多种材料的相关数据。
【目 录】
Preface
Acknowledgments
Introduction
Outline
References
Chapter1.Introduction to Wave Equations and Electromagnetic Constitutive Parameters
1.1 Maxwell'sEquations and Field Sources
1.2 Permittivityand Charge
1.3 Permeabilityand Current
1.4 WaveEquations for Homogeneous and Inhomogeneous Materials
1.5 HomogeneousPropagation in Linear Media
1.6 Conclusion
References
Chapter2.Sources and Dispersion for Polarization and Permittivity ε(f)
2.1 Sources ofPermittivity, Resistivity, and Conductivity in Materials
2.2 ModelingMaterial Complex Permittivity and Its Frequency Dependence
2.3 SmallDamping, τ=0
2.4 DC, Zero Frequency, and DC ScaledPermittivity
2.5 CombinedModels for Permittivity
2.6 CouplingPermittivity and Permeability
2.7 AdditionalBound Charge Contributions to Permittivity and Frequency Dispersion
2.8 PermittivityVariation with Temperature
References
Chapter3.Sources and Dispersion of Magnetization and Permeabilityμ(f)
3.1 Sources ofPermeability
3.2 FrequencyDispersion in Magnetic Materials
3.3Susceptibility Models for Data Analysis
3.4 An Overviewof Micromagnetic Models
3.5 Kramers—Kronig (KK) Relationships
3.6Temperature—Dependent Permeability
References
Chapter 4.FundamentalObservables for Material Measurement
4.1 Introduction
4,2 Scattering ofPlane Waves from Homogeneous Planar Boundaries and Material Slabs
4.3 SinglePlanar Slab of Material
4.4 Scattering: Cascade MatrixMethod for Multi—Boundary Material Analysis
4.5 Scatteringfrom a Shunt Planar Impedance Sheet
4.6 Transmissionand Reflection from Anisotropic Laminates
4.7 A Numerical AnisotropicMaterial Example
4.8 Conclusion
References
Chapter5.Composites and Effective Medium Theories
5.1 Introduction
5.2 EMTDevelopment Timeline
5.3 Limitationsand Derivation of EMTs
5.4 ScatteringFunctions for Spheres
5.5 Scatteringand EMT of Large—Aspect Ratio Particle Geometries
5.6 LayeredInclusions
5.7 ModelChoices: Importance ofConduction and Particulate Interaction
References
Chapter6.Conducting—Dielectric and Magneto—Dielectric Composites
6.1 Introduction
6.2 Percolation, Dimensionality, Depolarization, and FrequencyDispersion in Semiconducting, Conducting—Dielectric Composites
6.3 MagneticEffective Media
References
Chapter7.Numerical Models of Composites
7.1 Method ofMoment Modeling and Laminated Composites
7.2 FiniteDifference Time Domain Simulations
7.3 Comments forChapters 5 to 7
References
Chapter 8.ElectromagneticMeasurement Systems Summary for RF—Millimeter Wavelengths
8.1 AnIntroduction to Wideband Material Metrology
8.2 ErrorCorrection, Calibration, and Causality
8.3 Historical: Von Hippel andthe Slotted Line
8.4 Summary ofMeasurement Techniques
8.5 NonresonantTechniques: General Transmission Line Measurement Guidelines and Procedures
8.6 CylindricalWaveguide
8.7 CoaxialLines
8.8 StriplineMeasurements
8.9 Focused BeamFree Space System
8.10 FocusedBeam Technical Description
8.11 Calibration, Measurements, and Discussion
References
Chapter9.Resonant Techniques for Material Characterization
9.1 ResonantCavities
9.2 Overview ofthe TE10p Measurement Technique
9.3 ParallelPlate Stripline (TEM) Cavity
9.4 ClosedReflection Cavity
9.5 Open Cavity: Fabry—Perot Resonator
References
Chapter10.Transmission Line, Free Space Focused Beam and TE10N Measurement Details
10.1Constitutive Parameter Solutions in Coaxial Transmission Line, RectangularWaveguide, and Free Space
10.2 ExtremeElevated Temperature Reflection Measurements
10.3 Free SpaceFocused Beam Characterization of Materials
10.4 TEIONTransmission Cavity
References
Chapter 11.Micrometerand Nanoscale Composites
11.1Applications and Impetus for Nano Magnetic Composites
11.2 Case Study1: NiZn and MnZnFerrites
11.3 Case Study2: Nano MagneticComposites
11.4 Case Study3: Multiscale EMT (Nano to Macro) for ArtificialDielectrics
11.5 Conclusions
References
Chapter12.Measured Data of Materials and Composites
12.1 SolidCeramic versus Frequency
12.2 SolidCeramic versus Temperature
12.3 CeramicFiber versus Temperature
12.4 Two—PhaseFerrite—Polymer Composites and Three—Phase Ferrite—Fe—Polymer Composites
12.5 CompositesDemonstrating Percolation
12.6 SolidSemiconductors versus Frequency
12.7 Honeycomband Foams versus Frequency
12.8 Polymersversus Frequency
12.9 R—Cardsversus Frequency
12.10 Micrometerand Nanometer Magnetite Magnetic Composites versus Frequency
12.11Iron—Polymer Composites versus Frequency
12.12 CeramicPolvmer Fiber versus Frequency
12.13 DenseFerrites versus Frequency
12.14Fiber—Polymer Composites versus Frequency
Index
