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Tunable materials with applications in antennas and microwaves /

By: Sahalos, John N [author.].
Contributor(s): Kyriacou, George A.
Material type: materialTypeLabelBookSeries: Synthesis digital library of engineering and computer science: ; Synthesis lectures on antennas: #13Publisher: [San Rafael, California] : Morgan & Claypool, [2019]Description: 1 PDF (xxiii, 228 pages) : illustrations (chiefly color).Content type: text Media type: electronic Carrier type: online resourceISBN: 9781681736327.Subject(s): Antennas (Electronics) -- Materials | Microwave devices -- Materials | Ferrites (Magnetic materials) | Ferroelectric devices | antennas | microwaves | tunable materials | ferrites | ferroelectrics | multiferroics | transmission linesDDC classification: 621.382/4 Online resources: Abstract with links to full text | Abstract with links to resource Also available in print.
Contents:
1. Ferrites and ferroelectrics -- 1.1. Tunable electromagnetic materials -- 1.2. Overview of the evolution of ferrites -- 1.3. Ferroelectrics -- 1.4. Ferrite-ferroelectric films -- 1.5. Tunable frequency selective surfaces (FSSS) -- 1.6. References
2. Tunable materials-characteristics and constitutive parameters -- 2.1. Introduction -- 2.2. Microwave ferrites -- 2.3. Ferrimagnetics : ferrite materials and magnetic garnets -- 2.4. Ferrite films -- 2.5. Ferrite films and MMIC combatibility -- 2.6. Ferrite constitutive relations -- 2.7. Dielectric properties of ferrites -- 2.8. Ferroelctric properties -- 2.9. Ferroelectricity -- 2.10. Hysteresis loop -- 2.11. Ferroelectric materials--perovskites -- 2.12. The perovskite crystal structure -- 2.13. Ferroelectricity as a result of crystallic asymmetry -- 2.14. Paraelectric phase -- 2.15. Quantum or incipient ferroelectric -- 2.16. Perovskite superlattices -- 2.17. Conventional ferroelectrics--temperature and DC bias dependence -- 2.18. Superconductor perovskites -- 2.19. Ferroelectric layers and electrode interfaces -- 2.20. Hysteresis loop of ferroelectrics -- 2.21. Theory of the ferroelectric dielectric response -- 2.22. Ferroelectric tunability -- 2.23. Ferroelectric microwave losses -- 2.24. References
3. Finite ferrite samples -- 3.1. Demagnitization factors and ferrite samples -- 3.2. Spin waves and magnetostatic waves -- 3.3. Low- vs. High-order spin waves -- 3.4. Magnetostatic modes -- 3.5. Spin-wave spectrum manifold -- 3.6. Exchange-field interaction -- 3.7. Anisotropy energy -- 3.8. Magnetization equation for spin waves -- 3.9. Spin waves as magnons -- 3.10. Spin waves in an infinite medium -- 3.11. Spin waves including dipolar interactions -- 3.12. Spin-waves accounting for dipole-dipole interaction -- 3.13. Spin-wave manifold -- 3.14. Preliminaries to spin-wave excitation -- 3.15. Spin waves in a finite sample -- 3.16. Magnetostatic waves -- 3.17. Susceptibility and Characteristic Equation-Uniform Mode -- 3.18. The magnetostatic equation of a uniformly biased specimen -- 3.19. Magnetostatic modes in an infinite medium -- 3.20. Magnetostatic manifold -- 3.21. Magnetostatic modes of an infinitely extending thin slab film -- 3.22. Longitudinally magnetized infinitely extending thin slabs -- 3.23. Magnetostatic surface waves (1 +X)>0 -- 3.24. Magnetostatic waves on multilayer and grounded structures -- 3.25. Transversely biased grounded dielectric-ferrite layers -- 3.26. Shielded dielectric-ferrite layers -- 3.27. Longitudinally magnetized shielded dielectric ferrite layers -- 3.28. Magnetized and spin waves in ferrite slab with losses -- 3.29. Magnetostatic wave spectrum in the presence of losses -- 3.30. References
4. Multiferroics : ferrite-ferroelectric composites -- 4.1. Introduction -- 4.2. Multiferroic properties -- 4.3. Topologies--connectivity at two-phase composites -- 4.4. Multiferroics constitutive relations -- 4.5. References
5. Planar transmission lines -- 5.1. Introduction -- 5.2. Multilayer microstrip lines -- 5.3. Three-layers microstrip line -- 5.4. Multiple dielectric layer microstrip line -- 5.5. Frequency dispersion of multilayer microstrip lines -- 5.6. Equivalent single-layer microstrip (SLR) -- 5.7. Characteristic impedance vs. frequency, Z[alpha](f) -- 5.8. Dielectric losses -- 5.9. Coplanar transmission lines -- 5.10. Multilayer coplanar waveguide (CPW) -- 5.11. Symmetric multilayer coplanar waveguides (w1 = w2 = w) -- 5.12. Multilayer CPW with finite ground planes -- 5.13. Multilayer coplanar strips -- 5.14. Microstrip line on a single magnetic substrate -- 5.15. Microstrip on a single anisotropic dielectric substrate -- 5.16. Microstrip printed on a weakly magnetized ferrite-dielectric substrate -- 5.17. Microstrip lines on gyrotropic substrate -- 5.18. TEM duality principle in gyrotropic media -- 5.19. References.
Summary: Tunable Materials with Applications in Antennas and Microwaves is a stimulating topic in these modern times. With the explosion of the new generation of the wireless world, greater emphasis than ever before is being placed on the analysis and applications of modern materials. This book describes the characteristics of Ferrites and Ferroelectrics and introduces the reader to Multiferroics. 1. Represents, in a simple manner, the solid state physics and explains the permittivity and permeability tensor characteristics for the tunable materials of infinite and finite dimensions. 2. Gives the applications of tunable materials in resonators, filters, microstrips, striplines, antennas, phase shifters, capacitors, varactors, and frequency selective surfaces. 3. Describes in detail the mathematical analysis for spin and magnetostatic waves for infinite medium, thin slab films, and finite circular discs. The analysis contains original work, which the reader may extend in the future. 4. Provides multiferroics, which are ferrite and ferroelectric composites. Multiferroics are very promising tunable materials which are believed will offer many applications in the near future. 5. Contains the planar transmission lines with analytic formulas for multilayer microstrips, transmission lines, and waveguides with isotropic as well as anisotropic dielectric and magnetic materials. Also, gives the formulas to analyze the layered category of transmission lines with multiferroics. This book is intended for antenna and microwave engineers as well as for graduate students of Materials Science and Engineering, Electrical & Computer Engineering, and Physics Departments.
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E books E books PK Kelkar Library, IIT Kanpur
Available EBKE933
Total holds: 0

Mode of access: World Wide Web.

System requirements: Adobe Acrobat Reader.

Part of: Synthesis digital library of engineering and computer science.

Includes bibliographical references.

1. Ferrites and ferroelectrics -- 1.1. Tunable electromagnetic materials -- 1.2. Overview of the evolution of ferrites -- 1.3. Ferroelectrics -- 1.4. Ferrite-ferroelectric films -- 1.5. Tunable frequency selective surfaces (FSSS) -- 1.6. References

2. Tunable materials-characteristics and constitutive parameters -- 2.1. Introduction -- 2.2. Microwave ferrites -- 2.3. Ferrimagnetics : ferrite materials and magnetic garnets -- 2.4. Ferrite films -- 2.5. Ferrite films and MMIC combatibility -- 2.6. Ferrite constitutive relations -- 2.7. Dielectric properties of ferrites -- 2.8. Ferroelctric properties -- 2.9. Ferroelectricity -- 2.10. Hysteresis loop -- 2.11. Ferroelectric materials--perovskites -- 2.12. The perovskite crystal structure -- 2.13. Ferroelectricity as a result of crystallic asymmetry -- 2.14. Paraelectric phase -- 2.15. Quantum or incipient ferroelectric -- 2.16. Perovskite superlattices -- 2.17. Conventional ferroelectrics--temperature and DC bias dependence -- 2.18. Superconductor perovskites -- 2.19. Ferroelectric layers and electrode interfaces -- 2.20. Hysteresis loop of ferroelectrics -- 2.21. Theory of the ferroelectric dielectric response -- 2.22. Ferroelectric tunability -- 2.23. Ferroelectric microwave losses -- 2.24. References

3. Finite ferrite samples -- 3.1. Demagnitization factors and ferrite samples -- 3.2. Spin waves and magnetostatic waves -- 3.3. Low- vs. High-order spin waves -- 3.4. Magnetostatic modes -- 3.5. Spin-wave spectrum manifold -- 3.6. Exchange-field interaction -- 3.7. Anisotropy energy -- 3.8. Magnetization equation for spin waves -- 3.9. Spin waves as magnons -- 3.10. Spin waves in an infinite medium -- 3.11. Spin waves including dipolar interactions -- 3.12. Spin-waves accounting for dipole-dipole interaction -- 3.13. Spin-wave manifold -- 3.14. Preliminaries to spin-wave excitation -- 3.15. Spin waves in a finite sample -- 3.16. Magnetostatic waves -- 3.17. Susceptibility and Characteristic Equation-Uniform Mode -- 3.18. The magnetostatic equation of a uniformly biased specimen -- 3.19. Magnetostatic modes in an infinite medium -- 3.20. Magnetostatic manifold -- 3.21. Magnetostatic modes of an infinitely extending thin slab film -- 3.22. Longitudinally magnetized infinitely extending thin slabs -- 3.23. Magnetostatic surface waves (1 +X)>0 -- 3.24. Magnetostatic waves on multilayer and grounded structures -- 3.25. Transversely biased grounded dielectric-ferrite layers -- 3.26. Shielded dielectric-ferrite layers -- 3.27. Longitudinally magnetized shielded dielectric ferrite layers -- 3.28. Magnetized and spin waves in ferrite slab with losses -- 3.29. Magnetostatic wave spectrum in the presence of losses -- 3.30. References

4. Multiferroics : ferrite-ferroelectric composites -- 4.1. Introduction -- 4.2. Multiferroic properties -- 4.3. Topologies--connectivity at two-phase composites -- 4.4. Multiferroics constitutive relations -- 4.5. References

5. Planar transmission lines -- 5.1. Introduction -- 5.2. Multilayer microstrip lines -- 5.3. Three-layers microstrip line -- 5.4. Multiple dielectric layer microstrip line -- 5.5. Frequency dispersion of multilayer microstrip lines -- 5.6. Equivalent single-layer microstrip (SLR) -- 5.7. Characteristic impedance vs. frequency, Z[alpha](f) -- 5.8. Dielectric losses -- 5.9. Coplanar transmission lines -- 5.10. Multilayer coplanar waveguide (CPW) -- 5.11. Symmetric multilayer coplanar waveguides (w1 = w2 = w) -- 5.12. Multilayer CPW with finite ground planes -- 5.13. Multilayer coplanar strips -- 5.14. Microstrip line on a single magnetic substrate -- 5.15. Microstrip on a single anisotropic dielectric substrate -- 5.16. Microstrip printed on a weakly magnetized ferrite-dielectric substrate -- 5.17. Microstrip lines on gyrotropic substrate -- 5.18. TEM duality principle in gyrotropic media -- 5.19. References.

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Tunable Materials with Applications in Antennas and Microwaves is a stimulating topic in these modern times. With the explosion of the new generation of the wireless world, greater emphasis than ever before is being placed on the analysis and applications of modern materials. This book describes the characteristics of Ferrites and Ferroelectrics and introduces the reader to Multiferroics. 1. Represents, in a simple manner, the solid state physics and explains the permittivity and permeability tensor characteristics for the tunable materials of infinite and finite dimensions. 2. Gives the applications of tunable materials in resonators, filters, microstrips, striplines, antennas, phase shifters, capacitors, varactors, and frequency selective surfaces. 3. Describes in detail the mathematical analysis for spin and magnetostatic waves for infinite medium, thin slab films, and finite circular discs. The analysis contains original work, which the reader may extend in the future. 4. Provides multiferroics, which are ferrite and ferroelectric composites. Multiferroics are very promising tunable materials which are believed will offer many applications in the near future. 5. Contains the planar transmission lines with analytic formulas for multilayer microstrips, transmission lines, and waveguides with isotropic as well as anisotropic dielectric and magnetic materials. Also, gives the formulas to analyze the layered category of transmission lines with multiferroics. This book is intended for antenna and microwave engineers as well as for graduate students of Materials Science and Engineering, Electrical & Computer Engineering, and Physics Departments.

Also available in print.

Title from PDF title page (viewed on September 27, 2019).

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