Premium
An improved dispersion relation for parallel propagating electromagnetic waves in warm plasmas: Application to electron scattering
Author(s) -
Chen Lunjin,
Thorne Richard M.,
Shprits Yuri,
Ni Binbin
Publication year - 2013
Publication title -
journal of geophysical research: space physics
Language(s) - English
Resource type - Journals
eISSN - 2169-9402
pISSN - 2169-9380
DOI - 10.1002/jgra.50260
Subject(s) - dispersion relation , electron , scattering , atomic physics , physics , plasma , electromagnetic radiation , electromagnetic electron wave , dispersion (optics) , cyclotron , pitch angle , computational physics , optics , nuclear physics , geophysics
An improved dispersion relation, with thermal corrections retained, for parallel propagating electromagnetic waves in a warm plasma is developed for both left‒hand (L‒) and right‒hand (R‒) polarized modes. Compared with the cold plasma dispersion relation, the derived dispersion relation is in much better agreement with the full hot plasma dispersion relation (including the wave growth rate). The pitch angle scattering rates of energetic electrons are compared between using cold and full dispersion relation. Significant differences are found when evaluating pitch angle scattering rate of MeV electron caused by He + band waves in multiple ion plasmas. Due to He + ion cyclotron absorption, the He + band electromagnetic ion cyclotron waves, which are able to resonate with MeV electrons (at large wave number), tend to be strongly suppressed. Less significant differences in scattering rate of electrons between using cold and hot dispersion relation are found in the case of L‒mode waves in single H + ion plasma and in the case of R‒mode waves.