Magnetosonic wave

A magnetosonic wave (also magnetoacoustic wave) is a longitudinal wave^[1] of ions (and electrons) in a magnetized plasma propagating perpendicular to the stationary magnetic field. The wave is dispersionless with a phase velocity ω/k given by

{\frac {\omega ^{2}}{k^{2}}}=c^{2}\,{\frac {v_{s}^{2}+v_{A}^{2}}{c^{2}+v_{A}^{2}}}

where v_s is the speed of the ion acoustic wave, v_A is the speed of the Alfvén wave, and c is the speed of light in vacuum.

In the limit of low magnetic field (v_A→0), the wave turns into an ordinary ion acoustic wave. In the limit of low temperature (v_s→0), the wave becomes a modified Alfvén wave. Because the phase velocity of the magnetosonic mode is almost always larger than v_A, the magnetosonic wave is often called the "fast" hydromagnetic wave.

Both fast and slow magnetoacoustic waves have been recently discovered in the solar corona,^[2] which created an observational foundation for the novel technique for the coronal plasma diagnostics, coronal seismology.

References

↑ The wave is longitudinal in the perturbation of the fluid velocity, although the perturbation of the magnetic field is transverse. See Schmidt, Physics of High Temperature Plasmas, p.101.
↑ Nakariakov, V.M.; Verwichte, E. (2005). "Coronal waves and oscillations". Living Rev. Solar Phys. 2: 3.

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Magnetosonic wave

See also

References