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Книги з теми "Electric Arc Plasma"

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Автор: Grafiati
Опубліковано: 10 грудня 2022
Оновлено: 28 січня 2023

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Ознайомтеся з топ-37 книг для дослідження на тему "Electric Arc Plasma".

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1

Aubrecht, V. Spectral and equidensitometry diagnostics of electric arc plasma. Tomsk: Tomsk Polytechnical Univ., 1999.

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2

Krouchinin, Anatoli M. Modelling of the constricted arc in plasma generators. Częstochowa: Publishing Office of Czestochowa University of Technology, 2005.

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3

Aubrecht, V. Radiative transport of energy in SF₆ arc plasma. Tomsk: [s.n], 2000.

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4

Zhukov, M. F., and I. M. Zasypkin. Ėlektrodugovye generatory termicheskoĭ plazmy. Novosibirsk: "Nauka", 1999.

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5

Montgomery, R. W. The use of plasma torches for auxiliary heating in an electric arc furnace. Luxembourg: Commission of the European Communities, 1985.

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6

M, Oks E., and Brown Ian G, eds. Emerging applications of vacuum-arc-produced plasma, ion, and electron beams. Dordrecht: Kluwer Academic Publishers, 2003.

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7

International Power Beam Conference (1988 San Diego, Calif.). Power beam processing: Electron, laser, plasma-arc : proceedings of the International Power Beam Conference, 2-4 May 1988, San Diego, California, USA. [Metals Park, Ohio]: ASM International, 1988.

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8

Cyclic plasticity and low cycle fatigue life of metals. Amsterdam: Elsevier, 1991.

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9

NCCER. 29103-09 Plasma Arc Cutting. Pearson Education, Limited, 2014.

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10

NCCER. 29205-03 Plasma Arc Cutting (PAC) IG. Pearson Education, Limited, 2003.

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11

NCCER. 29103-14 Plasma Arc Cutting Trainee Guide. Pearson Education, Limited, 2015.

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12

Lakomskii, V. I. Alloying Liquid Metal with Nitrogen from Electric ARC Plasma. Cambridge International Science Publishing, 1999.

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13

Recommended practices for shielding gases for welding and plasma arc cutting. Miami, Fla: American Welding Society, 1993.

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14

A, Mantenieks Maris, and United States. National Aeronautics and Space Administration., eds. Performance and lifetime assessment of MPD arc thruster technology. [Washington, DC]: National Aeronautics and Space Administration, 1988.

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15

Metcalf, Myers Roger, and United States. National Aeronautics and Space Administration., eds. Mechanisms of anode power deposition in a low pressure free burning arc. [Washington, DC]: National Aeronautics and Space Administration, 1994.

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16

Metcalf, Myers Roger, and United States. National Aeronautics and Space Administration., eds. Mechanisms of anode power deposition in a low pressure free burning arc. [Washington, DC]: National Aeronautics and Space Administration, 1994.

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17

Fedorovich, Zhukov Mikhail, Koroteev Anatoliĭ Sazonovich, and Institut teplofiziki (Akademii͡a︡ nauk SSSR), eds. Teorii͡a︡ termicheskoĭ ėlektrodugovoĭ plazmy. Novosibirsk: Izd-vo "Nauka," Sibirskoe otd-nie, 1987.

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18

E, Nakori͡a︡kov V., and Institut teplofiziki (Akademii͡a︡ nauk SSSR), eds. Generat͡s︡ii͡a︡ potokov ėlektrodugovoĭ plazmy: Sbornik nauchnykh stateĭ. Novosibirsk: Akademii͡a︡ nauk SSSR, Sibirskoe otd-nie, In-t teplofiziki, 1987.

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19

Nestat͡s︡ionarnye dugovye i priėlektrodnye prot͡s︡essy v ėlektricheskikh apparatakh i plazmotronakh: Sbornik dokladov Vsesoi͡u︡znogo seminara, 24-29 ii͡u︡ni͡a︡ 1991 g., g. Ulan-Udė. Alma-Ata: Izd-vo "Gylym", 1991.

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20

TIG and Plasma Welding: Process Techniques, Recommended Practices and Applications. Woodhead Publishing, 1990.

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21

Lucas, W. Tig and Plasma Welding: Process Techniques, Recommended Practices and Applications. Elsevier Science & Technology, 1990.

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22

Theory of Thermal Electric Arc Plasmas. Springer-Verlag, 1995.

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23

Electrical Safety in Arc Welding. Health and Safety Executive (HSE), 1994.

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24

Final report for a preliminary investigation of Hall thruster technology: NAG3-1504. [Washington, DC: National Aeronautics and Space Administration, 1997.

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25

P, Volchkov Ė, Zhukov Mikhail Fedorovich, Institut teplofiziki (Akademii͡a︡ nauk SSSR), Institut teplofiziki (Rossiĭskai͡a︡ akademii͡a︡ nauk), and Institut teoreticheskoĭ i prikladnoĭ mekhaniki (Rossiĭskai͡a︡ akademii͡a︡ nauk), eds. Nizkotemperaturnai͡a︡ plazma. Novosibirsk: "Nauka," Sibirskoe otd-nie, 1990.

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26

Nikolaevich, Devi͡a︡tov Boris, Novikov O. I͡A︡, and Institut teplofiziki (Akademii͡a︡ nauk SSSR), eds. Matematicheskie metody issledovanii͡a︡ dinamiki i problemy upravlenii͡a︡ nizkotemperaturnoĭ plazmoĭ. Novosibirsk: "Nauka," Sibirskoe otd-nie, 1991.

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27

S, Ėngelʹsht V., Uri͡u︡kov B. A, and Institut teplofiziki (Akademii͡a︡ nauk SSSR), eds. Teorii͡a︡ stolba ėlektricheskoĭ dugi. Novosibirsk: "Nauka," Sibirskoe otd-nie, 1990.

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28

(Editor), Efim Oks, and Ian Brown (Editor), eds. Emerging Applications of Vacuum-Arc-Produced Plasma, Ion and Electron Beams (Nato Science Series II : Mathematics, Physics and Chemistry, Volume 88). Springer, 2003.

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29

(Editor), Efim Oks, and Ian Brown (Editor), eds. Emerging Applications of Vacuum-Arc-Produced Plasma, Ion and Electron Beams (NATO Science Series II: Mathematics, Physics and Chemistry). Springer, 2003.

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30

Woodson, Steven Wayne. An investigation of unipolar arcing at atmospheric pressure in Aluminum 2024 and aluminum coated glass slides. 1987.

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31

Morawetz, Klaus. Deep Impurities with Collision Delay. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198797241.003.0017.

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Анотація:
The linearised nonlocal kinetic equation is solved analytically for impurity scattering. The resulting response function provides the conductivity, plasma oscillation and Fermi momentum. It is found that virial corrections nearly compensate the wave-function renormalizations rendering the conductivity and plasma mode unchanged. Due to the appearance of the correlated density, the Luttinger theorem does not hold and the screening length is influenced. Explicit results are given for a typical semiconductor. Elastic scattering of electrons by impurities is the simplest but still very interesting dissipative mechanism in semiconductors. Its simplicity follows from the absence of the impurity dynamics, so that individual collisions are described by the motion of an electron in a fixed potential.
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32

Close, Frank. 3. Powerful forces. Oxford University Press, 2015. http://dx.doi.org/10.1093/actrade/9780198718635.003.0003.

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Анотація:
Why do atomic nuclei exist at all? A large nucleus contains many protons in close proximity. Why do these protons, all with the same electrical charge, not mutually repel? ‘Powerful forces’ shows the answer: a strong attractive force that acts between neutrons and protons when they are in contact with one another. Further studies of atomic structure have revealed that protons and neutrons are not fundamental particles. They consist of smaller particles: pions, which are made up of quarks that possess a ‘colour’ charge. The relativistic quantum theory of colour, known as quantum chromo-dynamics (QCD), is described along with ‘quark–gluon plasma’.
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33

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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Анотація:
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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34

Basu, Prasanta Kumar, Bratati Mukhopadhyay, and Rikmantra Basu. Semiconductor Nanophotonics. Oxford University PressOxford, 2022. http://dx.doi.org/10.1093/oso/9780198784692.001.0001.

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Abstract Nanometre sized structures made of semiconductors, insulators and metals and grown by modern growth technologies or by chemical synthesis exhibit novel electronic and optical phenomena due to confinement of electrons and photons. Strong interactions between electrons and photons in narrow regions lead to inhibited spontaneous emission, thresholdless laser operation, and Bose Einstein condensation of exciton-polaritons in microcavities. Generation of sub-wavelength radiation by surface Plasmon-polaritons at metal-semiconductor interfaces, creation of photonic band gap in dielectrics, and realization of nanometer sized semiconductor or insulator structures with negative permittivity and permeability, known as metamaterials, are further examples in the area of nanophotonics. The studies help develop Spasers and plasmonic nanolasers of subwavelength dimensions, paving the way to use plasmonics in future data centres and high speed computers working at THz bandwidth with less than a few fJ/bit dissipation. The present book intends to serveas a textbook for graduate students and researchers intending to have introductory ideas of semiconductor nanophotonics. It gives an introduction to electron-photon interactions in quantum wells, wires and dots and then discusses the processes in microcavities, photonic band gaps and metamaterials and related applications. The phenomena and device applications under strong light-matter interactions are discussed by mostly using classical and semi-classical theories. Numerous examples and problems accompany each chapter.
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35

Metcalf, Myers Roger, and Lewis Research Center, eds. Nonequilibrium in a low power arcjet nozzle. [Cleveland, Ohio]: National Aeronautics and Space Administration, Lewis Research Center, 1991.

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36

Mohan, Man, Anil Kumar Maini, and Aranya B. Bhattacherjee. Advances in Laser Physics and Technology. Edited by Anil K. Razdan. Foundation Books, 2014. http://dx.doi.org/10.1017/9789385386084.

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Анотація:
Lasers are created to study the timescale of electron motion in atoms and molecules. They also have wide applications in areas like solid state, plasma physics, nanoscience and defence technology. This book helps readers to master the large variety of physical phenomena and technological aspects involved in laser technology. Besides explaining the physical principles and common techniques of laser science and technology, it also elaborates on topics like High-harmonic Generation (HHG) and strong-field Non-sequential Double Ionization (NSDI), effects of a low energy atto-second pulse, laser spectroscopy, laser cooling and trapping, quantum optics and laser applications. Many important concepts covered include a new test system design of comprehensive characterization of non-imaging laser IR guided missiles, advanced laser and opto-electronics technologies for Low Intensity Conflict (LIC) applications and development of highly advanced laser cavity and resonator for high power chemical oxygen iodine laser at the Laser Science and Technology Centre (LASTEC).
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37

Horing, Norman J. Morgenstern. Quantum Statistical Field Theory. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198791942.001.0001.

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Анотація:
The methods of coupled quantum field theory, which had great initial success in relativistic elementary particle physics and have subsequently played a major role in the extensive development of non-relativistic quantum many-particle theory and condensed matter physics, are at the core of this book. As an introduction to the subject, this presentation is intended to facilitate delivery of the material in an easily digestible form to students at a relatively early stage of their scientific development, specifically advanced undergraduates (rather than second or third year graduate students), who are mathematically strong physics majors. The mechanism to accomplish this is the early introduction of variational calculus with particle sources and the Schwinger Action Principle, accompanied by Green’s functions, and, in addition, a brief derivation of quantum mechanical ensemble theory introducing statistical thermodynamics. Important achievements of the theory in condensed matter and quantum statistical physics are reviewed in detail to help develop research capability. These include the derivation of coupled field Green’s function equations of motion for a model electron-hole-phonon system, extensive discussions of retarded, thermodynamic and non-equilibrium Green’s functions, and their associated spectral representations and approximation procedures. Phenomenology emerging in these discussions includes quantum plasma dynamic, nonlocal screening, plasmons, polaritons, linear electromagnetic response, excitons, polarons, phonons, magnetic Landau quantization, van der Waals interactions, chemisorption, etc. Considerable attention is also given to low-dimensional and nanostructured systems, including quantum wells, wires, dots and superlattices, as well as materials having exceptional conduction properties such as superconductors, superfluids and graphene.
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