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Books on the topic 'Dielectic modes'

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Published: 10 December 2022
Last updated: 28 January 2023

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1

Francis, Robert M. A computer model for the transmission characteristics of dielectric radomes. Monterey, Calif: Naval Postgraduate School, 1992.

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2

1958-, Lu Yilong, ed. Microwave and optical waveguide analysis by the finite element method. Taunton, Somerset, England: Research Studies Press, 1996.

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3

Conference on Electrical Insulation and Dielectric Phenomena. Digest of literature on dielectrics: Aging models, mechanisms and reality. Edited by Sarjeant W. J. New York: IEEE, 1993.

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4

Kolundžija, Branko M. Electromagnetic modeling of composite metallic and dielectric structures. Boston: Artech House, 2002.

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5

Nemkov, V. S. Matematicheskoe modelirovanie ustroĭstv vysokochastotnogo nagreva. 2nd ed. Leningrad: "Politekhnika", 1991.

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6

Kołodziej, Hubert. Dielectric absorption in ferroelectrics of the order-disorder type, in particular of the K₄M(II)(CN)₆·3H₂O type of cyanocomplexes. Wrocław: Wydawn. Uniwersytetu Wrocławskiego, 1987.

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7

Kazarov, B. A. Modelirovanie i raschet teplovykh, ėlektricheskikh svoĭstv shirokozonnykh poluprovodnikov i diėlektrikov: (s defektami, fazovymi perekhodami i nanoklasterami). Georgievsk: Georgievskiĭ tekhnologicheskiĭ in-t GOU VPO "SevKavGTU", 2008.

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8

N, Robson P., and Kendall P. C, eds. Rib waveguide theory by the spectral index method. Taunton, Somerset, England: Research Studies Press, 1990.

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9

Magnetics, dielectrics, and wave propagation with MATLAB codes. Boca Raton: CRC Press, 2011.

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10

service), ScienceDirect (Online, ed. Dielectric elastomers as electromechanical transducers: Fundamentals, materials, devices, models and applications of an emerging electroactive polymer technology. Amsterdam: Elsevier, 2008.

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11

K, Dominek Allen, and Lewis Research Center, eds. Constitutive parameter de-embedding using inhomogeneously-filled rectangular waveguides with longitudinal section modes. Columbus, Ohio: Ohio State University, ElectroScience Laboratory, Dept. of Electrical Engineering, 1990.

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12

Horing, Norman J. Morgenstern. Random Phase Approximation Plasma Phenomenology, Semiclassical and Hydrodynamic Models; Electrodynamics. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198791942.003.0010.

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Chapter 10 reviews both homogeneous and inhomogeneous quantum plasma dielectric response phenomenology starting with the RPA polarizability ring diagram in terms of thermal Green’s functions, also energy eigenfunctions. The homogeneous dynamic, non-local inverse dielectric screening functions (K) are exhibited for 3D, 2D, and 1D, encompassing the non-local plasmon spectra and static shielding (e.g. Friedel oscillations and Debye-Thomas-Fermi shielding). The role of a quantizing magnetic field in K is reviewed. Analytically simpler models are described: the semiclassical and classical limits and the hydrodynamic model, including surface plasmons. Exchange and correlation energies are discussed. The van der Waals interaction of two neutral polarizable systems (e.g. physisorption) is described by their individual two-particle Green’s functions: It devolves upon the role of the dynamic, non-local plasma image potential due to screening. The inverse dielectric screening function K also plays a central role in energy loss spectroscopy. Chapter 10 introduces electromagnetic dyadic Green’s functions and the inverse dielectric tensor; also the RPA dynamic, non-local conductivity tensor with application to a planar quantum well. Kramers–Krönig relations are discussed. Determination of electromagnetic response of a compound nanostructure system having several nanostructured parts is discussed, with applications to a quantum well in bulk plasma and also to a superlattice, resulting in coupled plasmon spectra and polaritons.
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13

A, Fowler Howland, and Information Technology Laboratory (National Institute of Standards and Technology). Scalable Parallel Systems and Applications Group., eds. Dielectric breakdown in a simplified parallel model. Gaithersburg, MD: U.S. Dept. of Commerce, Technology Administration, National Institute of Standards and Technology, 1998.

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14

Lu, Dinghui. Pion-nucleon interactions in the chiral color dielectric model. 1995.

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15

Lu, Dinghui. Pion-nucleon interactions in the chiral color dielectric model. 1995.

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16

Vishakhadatta, Gannavaram D. Finite element modeling of dielectric waveguides. 1993.

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17

Canfield, Lingzhou Li. Local field effects on dielectric properties of solids. 1992.

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18

Chang, Hosung. Analysis of linear and nonlinear coupled dielectric waveguides. 1993.

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19

Kolundzija, Branko, and Antonije Djordjevic. Electromagnetic Modeling of Composite Metallic and Dielectric Structures. Artech House Publishers, 2002.

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20

Henriksen, Niels Engholm, and Flemming Yssing Hansen. Introduction to Condensed-Phase Dynamics. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198805014.003.0009.

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This chapter discusses chemical reactions in solution; first, how solvents modify the potential energy surface of the reacting molecules and second, the role of diffusion. As a first approximation, solvent effects are described by models where the solvent is represented by a dielectric continuum, focusing on the Onsager reaction-field model for solvation of polar molecules. The reactants of bimolecular reactions are brought into contact by diffusion, and the interplay between diffusion and chemical reaction that determines the overall reaction rate is described. The solution to Fick’s second law of diffusion, including a term describing bimolecular reaction, is discussed. The limits of diffusion control and activation control, respectively, are identified. It concludes with a stochastic description of diffusion and chemical reaction based on the Fokker–Planck equation, which includes the diffusion of particles interacting via a potential U(r).
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21

Haq, Qureshi A., and United States. National Aeronautics and Space Administration., eds. Review of slow-wave structures. [Washington, DC]: National Aeronautics and Space Administration, 1994.

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22

Review of slow-wave structures. [Washington, DC]: National Aeronautics and Space Administration, 1994.

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23

Haq, Qureshi A., and United States. National Aeronautics and Space Administration., eds. Review of slow-wave structures. [Washington, DC]: National Aeronautics and Space Administration, 1994.

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24

Haq, Qureshi A., and United States. National Aeronautics and Space Administration., eds. Review of slow-wave structures. [Washington, DC]: National Aeronautics and Space Administration, 1994.

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25

Handbook Of Dielectric And Thermal Properties Of Materials At Microwave Frequencies. Artech House Publishers, 2012.

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26

User's manual for three dimensional FDTD version A code for scattering from frequency-independent dielectric materials. University Park, PA: Electrical and Computer Engineering Dept., Pennsylvania State University, 1992.

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27

Carpi, Federico, Danilo De Rossi, Roy Kornbluh, Ronald Edward Pelrine, and Peter Sommer-Larsen. Dielectric Elastomers As Electromechanical Transducers: Fundamentals, Materials, Devices, Models and Applications of an Emerging Electroactive Polymer Technology. Elsevier Science & Technology Books, 2011.

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28

Magin, R. Fractional Calculus in Bioengineering, Part 2 : Fractional Calculus in Lumped Element Systems: Neuroscience, Dielectric and Viscoelastic Models. Begell House Publishers, Incorporated, 2021.

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29

Tanyer, Süleyman Gökhun. High frequency scattering by a conducting circular cylinder coated with a lossy dielectric of non uniform thickness. 1994.

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30

Horing, Norman J. Morgenstern. Interacting Electron–Hole–Phonon System. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198791942.003.0011.

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Chapter 11 employs variational differential techniques and the Schwinger Action Principle to derive coupled-field Green’s function equations for a multi-component system, modeled as an interacting electron-hole-phonon system. The coupled Fermion Green’s function equations involve five interactions (electron-electron, hole-hole, electron-hole, electron-phonon, and hole-phonon). Starting with quantum Hamilton equations of motion for the various electron/hole creation/annihilation operators and their nonequilibrium average/expectation values, variational differentiation with respect to particle sources leads to a chain of coupled Green’s function equations involving differing species of Green’s functions. For example, the 1-electron Green’s function equation is coupled to the 2-electron Green’s function (as earlier), also to the 1-electron/1-hole Green’s function, and to the Green’s function for 1-electron propagation influenced by a nontrivial phonon field. Similar remarks apply to the 1-hole Green’s function equation, and all others. Higher order Green’s function equations are derived by further variational differentiation with respect to sources, yielding additional couplings. Chapter 11 also introduces the 1-phonon Green’s function, emphasizing the role of electron coupling in phonon propagation, leading to dynamic, nonlocal electron screening of the phonon spectrum and hybridization of the ion and electron plasmons, a Bohm-Staver phonon mode, and the Kohn anomaly. Furthermore, the single-electron Green’s function with only phonon coupling can be rewritten, as usual, coupled to the 2-electron Green’s function with an effective time-dependent electron-electron interaction potential mediated by the 1-phonon Green’s function, leading to the polaron as an electron propagating jointly with its induced lattice polarization. An alternative formulation of the coupled Green’s function equations for the electron-hole-phonon model is applied in the development of a generalized shielded potential approximation, analysing its inverse dielectric screening response function and associated hybridized collective modes. A brief discussion of the (theoretical) origin of the exciton-plasmon interaction follows.
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31

Nagaosa, N. Multiferroics. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198787075.003.0010.

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This chapter delves into the physics of multiferroics, the recent developments of which are discussed here from the viewpoint of the spin current and “emergent electromagnetism” for constrained systems. It presents the three sources of U(1) gauge fields, namely, the Berry phase associated with the noncollinear spin structure, the spin-orbit interaction (SOI), and the usual electromagnetic field. The chapter reviews multiferroic phenomena in noncollinear magnets from this viewpoint and discusses theories of multiferroic behavior of cycloidal helimagnets in terms of the spin current or vector spin chirality. Relativistic SOI leads to a coupling between the spin current and the electric polarization, and hence the ferroelectric and dielectric responses are a new and important probe for the spin states and their dynamical properties. Microscopic theories of the ground state polarization for various electronic configurations, collective modes including the electromagnon, and some predictions including photoinduced chirality switching are discussed with comparison to experimental results.
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32

United States. National Aeronautics and Space Administration., ed. A model for the scattering of high-frequency electromagnetic fields from dielectrics exhibiting thermally-activated electrical losses. [Washington, DC]: National Aeronautics and Space Administration, 1991.

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33

United States. National Aeronautics and Space Administration., ed. A model for the scattering of high-frequency electromagnetic fields from dielectrics exhibiting thermally-activated electrical losses. [Washington, DC]: National Aeronautics and Space Administration, 1991.

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34

Fractional Kinetics In Solids Anomalous Charge Transport In Semiconductors Dielectrics And Nanosystems. World Scientific Publishing Company, 2011.

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35

Modified Hilbert transform pair and Kramers-Kronig relations for complex permittivities. Hampton, Va: National Aeronautics and Space Administration, Langley Research Center, 1990.

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36

Solymar, Laszlo, Donald Walsh, and Richard R. A. Syms. Electrical Properties of Materials. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198829942.001.0001.

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A classic text in the field providing a readable and accessible guide for students of electrical and electronic engineering. Fundamentals of electric properties of materials are illustrated and put into context with contemporary applications in engineering. Mathematical content is kept to a minimum allowing the reader to focus on the subject. The starting point is the behaviour of the electron, which is explored both in the classical and in the quantum-mechanical context. Then comes the study of bonds, the free electron model, band structure, and the theory of semiconductors, followed by a chapter on semiconductor devices. Further chapters are concerned with the fundamentals of dielectrics, magnetic materials, lasers, optoelectronics, and superconductivity. The last chapter is on metamaterials, which has been a quite popular subject in the past decade. The book includes problems, the worked solutions are available in a separate publication: Solutions manual for electrical properties of materials. There is an appendix giving a list of Nobel Prize winners whose work was crucial for describing the electric properties of materials, and there are further appendices giving descriptions of phenomena which did not fit easily within the main text. In particular there is a quite detailed appendix that summarizes the properties of memory elements. The book is ideal for undergraduates, and is also an invaluable reference for graduate students and others wishing to explore this rapidly changing field.
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37

United States. National Aeronautics and Space Administration., ed. The charging of composites in the space environment. [Washington, DC: National Aeronautics and Space Administration, 1997.

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38

Problemnye regiony resursnogo tipa: Azi︠a︡tskai︠a︡ chastʹ Rossiĭ. Novosibirsk: SO RAN, 2005.

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39

V, Bazarov B., ed. Problemnye regiony resursnogo tipa: Aziatskai︠a︡ chastʹ Rossii. Novosibirsk: Izd-vo Sibirskogo otd-nii︠a︡ Rossiĭskoĭ akademii nauk, 2005.

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