Electrostatic ion cyclotron wave

In plasma physics, an electrostatic ion cyclotron wave is a longitudinal oscillation of the ions (and electrons) in a magnetized plasma, propagating nearly (but not exactly) perpendicular to the magnetic field. The angle (in radians) between the direction of propagation and the direction perpendicular to the magnetic field must be greater than about the square root of the mass ratio,

${\displaystyle {\sqrt {\frac {m_{e}}{m_{i}}}}}$,

in order that the electrons can move along the field lines from crest to trough to satisfy the Boltzmann relation. The dispersion relation is

${\displaystyle \omega ^{2}=\Omega _{c}^{2}+k^{2}v_{s}^{2}}$,^[1]

where Ω_c is the ion cyclotron frequency and v_s is the ion sound speed. This relation is the result of restoring forces due to the Lorentz force (see Upper hybrid oscillation for more details), the electrostatic force (the T_e term in v_s), and the ion pressure (the T_i term in v_s).

See also

• Waves in plasmas
• Ion acoustic wave
• Upper hybrid oscillation
• Lower hybrid oscillation

References

1. Thomas Stix (1962). The Theory of Plasma Waves. McGraw-Hill.