Thermal effects in the dissipative instability of the electron beam-plasma systems

“…It is well known that the ion beam-plasma interaction is most significant when the Cherenkov resonant condition is satisfied [12,27]. Therefore, the solution of Equations (7) and (8) is…”

“…pi , the effect of the magnetic field on the dispersion relation of electromagnetic waves becomes considerable and must be taken into account. This case is specially applicable in a fully magnetized beam-plasma waveguide [6,12]. Here, we consider that the beam is directed strictly parallel to the external magnetic field and this field is so strong that it can freeze the transversal motion of the beam and plasma particles.…”

“…0. Using the corresponding dispersion relation of high-frequency waves, Equation (12), in both strongly magnetized and unmagnetized plasmas, it can be found that the cut-off frequency is equal to ! pe and beams with high velocity can interact with the plasma.…”

“…Therefore, in order to examine the exact behavior of plasma instabilities, it is essential to consider both thermal and collisional effects. These effects have been studied for the dissipative instability of a relativistic electron beam in a fully magnetized plasma waveguide by Shokri and Khorashadizadeh [12].…”

“…[12] for the interaction of an underlimiting electron beam with a fully magnetized plasma. Therefore, in this case the components of the dielectric tensor are…”

Ion beam driven instabilities in unmagnetized and strongly magnetized plasmas

“…It is well known that the ion beam-plasma interaction is most significant when the Cherenkov resonant condition is satisfied [12,27]. Therefore, the solution of Equations (7) and (8) is…”

“…pi , the effect of the magnetic field on the dispersion relation of electromagnetic waves becomes considerable and must be taken into account. This case is specially applicable in a fully magnetized beam-plasma waveguide [6,12]. Here, we consider that the beam is directed strictly parallel to the external magnetic field and this field is so strong that it can freeze the transversal motion of the beam and plasma particles.…”

“…0. Using the corresponding dispersion relation of high-frequency waves, Equation (12), in both strongly magnetized and unmagnetized plasmas, it can be found that the cut-off frequency is equal to ! pe and beams with high velocity can interact with the plasma.…”

“…Therefore, in order to examine the exact behavior of plasma instabilities, it is essential to consider both thermal and collisional effects. These effects have been studied for the dissipative instability of a relativistic electron beam in a fully magnetized plasma waveguide by Shokri and Khorashadizadeh [12].…”

“…[12] for the interaction of an underlimiting electron beam with a fully magnetized plasma. Therefore, in this case the components of the dielectric tensor are…”

Ion beam driven instabilities in unmagnetized and strongly magnetized plasmas

Anisotropic Plasma

Quantum Plasma: Influence of Spatial Dispersion on Some Phenomena in Metals