Microwave materials and applications

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Title:

Author:

Sebastian, M. T., 1952- editor.

ISBN:

9781119208549

9781119208556

Physical Description:

1 online resource

Contents:

Microwave Materials and Applications; Contents; List of Contributors; Series Preface; Wiley Series in Materials for Electronic and Optoelectronic Applications; Preface; 1 Measurement of Microwave Dielectric Properties and Factors Affecting Them; 1.1 Introduction; 1.2 Permittivity (r) and quality factor (Q); 1.3 Measurement of Microwave Dielectric Properties; 1.4 Methods of Measurement; 1.4.1 Hakki and Coleman (Courtney) Method; 1.4.2 TE01d Mode Dielectric Resonator Method; 1.4.3 Measurement of the Quality Factor by a Strip Line Excited Using the Cavity Method.

1.4.4 Whispering Gallery Mode (WGM) Resonators1.4.5 Split Post Dielectric Resonator (SPDR); 1.4.6 Cavity Perturbation Method; 1.4.7 TM0n0 Mode and Re-entrant Cavity Methods; 1.4.8 TE01n Mode Cavities; 1.4.9 Thin Samples and Free-Space Methods; 1.5 Measurement of EMI Shielding Effectiveness; 1.5.1 Waveguide Method; 1.6 Terahertz and Millimeter Wave Measurements; 1.6.1 Backward Wave Oscillator (BWO); 1.6.2 Terahertz Time-Domain Spectroscopy (THz-TDS); 1.7 Measurement of Dielectric Properties of Powder Samples; 1.8 Estimation of Dielectric Loss by Spectroscopic Methods.

1.9 Factors Affecting Dielectric Loss1.10 Measurement of Temperature Coefficient of Resonant Frequency; 1.11 Tuning of the Resonant Frequency; References; 2 Modeling of Microwave Dielectric Properties of Composites; 2.1 Introduction; 2.2 Connectivity; 2.3 Electrostatic Theory; 2.3.1 Polarizability; 2.3.2 Scattering; 2.3.3 Orientation; 2.4 Mixing Equations; 2.4.1 Clausius-Mossotti; 2.4.2 Maxwell-Garnett; 2.4.3 Bruggeman Symmetric; 2.4.4 Bruggeman Non-symmetric; 2.4.5 Sen Scala-Cohen; 2.4.6 Coherent Potential; 2.4.7 Looyenga; 2.4.8 Lichtenecker; 2.4.9 Modified Lichtenecker; 2.4.10 Differential.

2.4.11 General Mixing Model2.4.12 Effective Medium Theory (EMT); 2.4.13 Jayasundere-Smith; 2.4.14 Vo-Shi; 2.4.15 Interphase Power Law (IPL); 2.5 Effect of Porosity; 2.5.1 Permittivity; 2.5.2 Dielectric Losses; 2.5.3 Dielectric Properties of Powders; 2.6 Conclusion; References; 3 Perovskites; 3.1 Introduction; 3.2 Lattice Constant Prediction; 3.3 Tolerance Factor; 3.4 Octahedral Tilting; 3.5 Simple Perovskites; 3.5.1 LnAlO3 Type Materials; 3.5.2 Ag(Nb1-xTax)O3 Type Materials; 3.5.3 Ca-Based Perovskites; 3.6 Cation Ordering; 3.6.1 1:1 Ordered Perovskites; 3.6.2 1:2 Ordering; 3.6.3 1:3 Ordering.

3.6.4 1:2:1 Ordering3.7 Cation Deficient Perovskites; 3.8 Summary; References; 4 High Permittivity Materials; 4.1 Introduction; 4.2 The BaO-Ln2O3-TiO2 System; 4.2.1 Crystal Structure of Ba6-3xLn8+2xTi18O54; 4.2.2 Tolerance Factor and Its Effect on the Temperature Coefficient; 4.2.3 Microwave Dielectric Properties of BaO-Ln2O3-TiO2 System; 4.3 The Effect of Processing Parameters on Electrical Properties; 4.4 Titania; 4.5 Sr1-3x/2CexTiO3 Ceramics; 4.5.1 Crystal Structure of Sr1-3x/2CexTiO3 System; 4.5.2 Microstructure and Dielectric Properties of SCT ceramics; 4.5.3 (Sr0.75-xPbxCe0.167)TiO3.

Abstract:

The recent rapid progress in wireless telecommunication, including the Internet of Things, 5th generation wireless systems, satellite broadcasting, and intelligent transport systems has increased the need for low-loss dielectric materials and modern fabrication techniques. These materials have excellent electrical, dielectric, and thermal properties and have enormous potential, especially in wireless communication, flexible electronics, and printed electronics. Microwave Materials and Applications discusses the methods commonly employed for measuring microwave dielectric properties, the various attempts reported to solve problems of materials chemistry and crystal structure, doping, substitution, and composite formation, highlighting the processing techniques, morphology influences, and applications of microwave materials whilst summarizing many of the recent technical research accomplishments in the area of microwave dielectrics and applications Chapters examine: Oxide ceramics for dielectric resonators and substrates HTCC, LTCC and ULTCC tapes for substrates Polymer ceramic composites for printed circuit boards Elastomer-ceramic composites for flexible electronics Dielectric inks EMI shielding materials Microwave ferrites A comprehensive Appendix presents the fundamental properties for more than 4000 low-loss dielectric ceramics, their composition, crystal structure, and their microwave dielectric properties. Microwave Materials and Applications presents a comprehensive view of all aspects of microwave materials and applications, making it useful for scientists, industrialists, engineers, and students working on current and emerging applications of wireless communications and consumer electronics.

Local Note:

John Wiley and Sons

Subject Term:

Microwave devices -- Materials.

Dielectrics.

Dispositifs à micro-ondes -- Matériaux.

TECHNOLOGY & ENGINEERING -- Mechanical.

Materials Science.

TECHNOLOGY & ENGINEERING.

Dielectrics

Microwave devices -- Materials

Genre: