TY - JOUR
T1 - Physics of mass loaded plasmas
AU - Szegö, Károly
AU - Glassmeier, Karl-Heinz
AU - Bingham, Robert
AU - Bogdanov, Alexander
AU - Fischer, Christian
AU - Haerendel, Gerhard
AU - Brinca, Armando
AU - Cravens, Tom
AU - Dubinin, Eduard
AU - Sauer, Konrad
AU - Fisk, Len
AU - Gombosi, Tamas
AU - Schwadron, Nathan
AU - Isenberg, Phil
AU - Lee, Martin
AU - Mazelle, Christian
AU - Möbius, Eberhard
AU - Motschmann, Uwe
AU - Shapiro, Vitali D.
AU - Tsurutani, Bruce
AU - Zank, Gary
PY - 2000/12/1
Y1 - 2000/12/1
N2 - In space plasmas the phenomenon of mass loading is common. Comets are one of the most evident objects where mass loading controls to a large extent the structure and dynamics of its plasma environment. New charged material is implanted to the fast streaming solar wind by planets, moons, other solar system objects, and even by the interstellar neutral gas flowing through our solar system. In this review we summarize both the current observations and the relevant theoretical approaches. First we survey the MHD methods, starting with a discussion how mass loading affects subsonic and supersonic gasdynamics flows, continuing this with single and multi-fluid MHD approaches to describe the flow when mass, momentum and energy is added, and we finish this section by the description of mass loaded shocks. Next we consider the kinetic approach to the same problem, discussing wave excitations, pitch angle and energy scattering in linear and quasi-linear approximations. The different descriptions differ in assumptions and conclusions; we point out the differences, but it is beyond the scope of the paper to resolve all the conflicts. Applications of these techniques to comets, planets, artificial ion releases, and to the interplanetary neutrals are reviewed in the last section, where observations are also compared with models, including hybrid simulations as well. We conclude the paper with a summary of the most important open, yet unsolved questions.
AB - In space plasmas the phenomenon of mass loading is common. Comets are one of the most evident objects where mass loading controls to a large extent the structure and dynamics of its plasma environment. New charged material is implanted to the fast streaming solar wind by planets, moons, other solar system objects, and even by the interstellar neutral gas flowing through our solar system. In this review we summarize both the current observations and the relevant theoretical approaches. First we survey the MHD methods, starting with a discussion how mass loading affects subsonic and supersonic gasdynamics flows, continuing this with single and multi-fluid MHD approaches to describe the flow when mass, momentum and energy is added, and we finish this section by the description of mass loaded shocks. Next we consider the kinetic approach to the same problem, discussing wave excitations, pitch angle and energy scattering in linear and quasi-linear approximations. The different descriptions differ in assumptions and conclusions; we point out the differences, but it is beyond the scope of the paper to resolve all the conflicts. Applications of these techniques to comets, planets, artificial ion releases, and to the interplanetary neutrals are reviewed in the last section, where observations are also compared with models, including hybrid simulations as well. We conclude the paper with a summary of the most important open, yet unsolved questions.
KW - space plasmas
KW - mass loading
KW - comets
KW - plasmas
KW - solar wind
KW - solar system
U2 - 10.1023/A:1026568530975
DO - 10.1023/A:1026568530975
M3 - Article
SN - 0038-6308
VL - 94
SP - 429
EP - 671
JO - Space Science Reviews
JF - Space Science Reviews
IS - 3-4
ER -