Proceedings of the International School of Physics "Enrico Fermi.", Volume 25N. Zanichelli, 1953 - Nuclear physics |
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Page 180
Nonlinear Theory of Electrostatic Waves in Plasmas ( * ) . P. A. STURROCK Microwave Laboratory , W. W. Hansen Laboratories of Physics , Stanford ... plasma frequency given by ( P A STURROCK Nonlinear theory of electrostatic waves in plasmas.
Nonlinear Theory of Electrostatic Waves in Plasmas ( * ) . P. A. STURROCK Microwave Laboratory , W. W. Hansen Laboratories of Physics , Stanford ... plasma frequency given by ( P A STURROCK Nonlinear theory of electrostatic waves in plasmas.
Page 193
5. Coupling of plasma oscillations and electromagnetic waves . In the previous section , we considered the coupling of electrostatic waves among themselves and found that the coupling occurs basically in groups of ... WAVES IN PLASMAS 193.
5. Coupling of plasma oscillations and electromagnetic waves . In the previous section , we considered the coupling of electrostatic waves among themselves and found that the coupling occurs basically in groups of ... WAVES IN PLASMAS 193.
Page 197
... waves and one plasma oscillation , associated with the selection rules ( 7.1 ) WT1 = kr Ti = WT2 + Wp , T2 k12 + k1 . This would clearly give rise to a frequency shift between NONLINEAR THEORY OF ELECTROSTATIC WAVES IN PLASMAS 197.
... waves and one plasma oscillation , associated with the selection rules ( 7.1 ) WT1 = kr Ti = WT2 + Wp , T2 k12 + k1 . This would clearly give rise to a frequency shift between NONLINEAR THEORY OF ELECTROSTATIC WAVES IN PLASMAS 197.
Contents
W B THOMPSON Kinetic theory of plasma | 97 |
Topics in microinstabilities | 137 |
carrier mass | 159 |
Copyright | |
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adiabatic invariant amplitude approximation Boltzmann equation boundary conditions boundary layer calculated cathode coefficient collision components consider constant contraction corresponds courbe critère current density d³k d³v Debye length derived differential equations discharge dispersion relation distribution function eigenvalue electric field electrons and ions electrostatic energy principle equations of motion equilibrium exp[i(k finite fluid theory frequency given Hence instability integral interaction ionized k₁ KRUSKAL l'axe magnétique limit Liouville function lowest order magnetic field Maxwell's equations mode nonlinear obtain Ohm's law P₁ parameter particle périodique perturbation Phys plasma oscillations Plasma Physics Poisson's equation potential problem quantities R₁ region Rendiconti S.I.F. satisfied saturation current solution solving stabilité stability temperature thermal tion v₁ values variables vector velocity x₁ zero zero-order Απ