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200 10$aComputational physics of electric discharges in gas flows$b[electronic resource] /$fSergey T. Surzhikov
210   $aBerlin ;$aBoston $cDe Gruyter$d2013
215   $a1 online resource (440 p.)
225 0 $aDe Gruyter Studies in Mathematical Physics ;$v7
300   $aDescription based upon print version of record.
311 0 $a3-11-027041-2 
311 0 $a3-11-027033-1 
320   $aIncludes bibliographical references and index.
327   $tFront matter --$tPreface --$tContents --$tPart I. Elements of the theory of numerical modeling of gas-discharge phenomena --$tChapter 1. Models of gas-discharge physical mechanics --$tChapter 2. Application of numerical simulation models for the investigation of laser supported waves --$tChapter 3. Computational models of magnetohydrodynamic processes --$tPart II. Numerical simulation models of glow discharge --$tChapter 4. The physical mechanics of direct current glow discharge --$tChapter 5. Drift-diffusion model of glow discharge in an external magnetic field --$tPart III. Ambipolar models of direct current discharges --$tChapter 6. Quasi-neutral model of gas discharge in an external magnetic field and in gas flow --$tChapter 7. Viscous interaction on a flat plate with surface discharge in a magnetic field --$tChapter 8. Hypersonic flow of rarefied gas in a channel with glow discharge in an external magnetic field --$tChapter 9. Hypersonic flow of rarefied gas in a curvilinear channel with glow discharge --$tAppendix --$tBibliography --$tIndex
330   $aPhysical models of gas discharge processes in gas flows and numerical simulation methods, which are used for numerical simulation of these phenomena are considered in the book. Significant attention is given to a solution of two-dimensional problems of physical mechanics of electric arc, radio-frequency, micro-wave, and optical discharges, as well as to investigation of electrodynamic structure of direct current glow discharges. Problems of modern computational magnetohydrodynamics (MHD) are considered also. Prospects of the different kinds of discharges use in aerospace applications are discussed. This book is intended for scientists and engineers concerned with physical gas dynamics, physics of the low-temperature plasma and gas discharges, and also for students and post-graduate students of physical and technical specialties of universities.
410  3$aDe Gruyter Studies in Mathematical Physics
606   $aGlow discharges
606   $aElectric discharges through gases
608   $aElectronic books.
615  0$aGlow discharges.
615  0$aElectric discharges through gases.
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200 10$aDifferential forms in electromagnetics /$fIsmo V. Lindell
205   $a1st ed.
210  1$aPiscataway, New Jersey :$cIEEE Press,$dc2004.
210  2$a[Piscataqay, New Jersey] :$cIEEE Xplore,$d[2005]
215   $a1 PDF ([xv], 253 pages) $cillustrations
225 1 $aIEEE Press series on electromagnetic wave theory ;$v27
300   $aBibliographic Level Mode of Issuance: Monograph
311   $a0-471-64801-9 
320   $aIncludes bibliographical references and index.
327   $aMultivectors -- Dyadic algebra -- Differential forms -- Electromagnetic fields and sources -- Medium, boundary, and power conditions -- Theorems and transformations -- Electromagnetic waves.
330   $aAn introduction to multivectors, dyadics, and differential forms for electrical engineers While physicists have long applied differential forms to various areas of theoretical analysis, dyadic algebra is also the most natural language for expressing electromagnetic phenomena mathematically. George Deschamps pioneered the application of differential forms to electrical engineering but never completed his work. Now, Ismo V. Lindell, an internationally recognized authority on differential forms, provides a clear and practical introduction to replacing classical Gibbsian vector calculus with the mathematical formalism of differential forms. In Differential Forms in Electromagnetics, Lindell simplifies the notation and adds memory aids in order to ease the reader's leap from Gibbsian analysis to differential forms, and provides the algebraic tools corresponding to the dyadics of Gibbsian analysis that have long been missing from the formalism. He introduces the reader to basic EM theory and wave equations for the electromagnetic two-forms, discusses the derivation of useful identities, and explains novel ways of treating problems in general linear (bi-anisotropic) media. Clearly written and devoid of unnecessary mathematical jargon, Differential Forms in Electromagnetics helps engineers master an area of intense interest for anyone involved in research on metamaterials.
410  0$aIEEE Press series on electromagnetic wave theory ;$v27
606   $aElectromagnetism$xMathematics
606   $aDifferential forms
606   $aElectricity & Magnetism$2HILCC
606   $aPhysics$2HILCC
606   $aPhysical Sciences & Mathematics$2HILCC
610   $aElectrical and Electronics Engineering.
615  0$aElectromagnetism$xMathematics.
615  0$aDifferential forms.
615  7$aElectricity & Magnetism
615  7$aPhysics
615  7$aPhysical Sciences & Mathematics
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700   $aLindell$b Ismo V.$028593
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906   $aBOOK
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