Plasma Astrophysics, Part II: Reconnection and FlaresMagnetic ?elds are easily generated in astrophysical plasma owing to its ?6 high conductivity. Magnetic ?elds, having strengths of order few 10 G, correlated on several kiloparsec scales are seen in spiral galaxies. Their origin could be due to ampli?cation of a small seed ?eld by a turbulent galactic dynamo. In several galaxies, like the famous M51, magnetic ?elds are well correlated (or anti-correlated) with the optical spiral arms. These are the weakest large-scale ?elds observed in cosmic space. The strongest magnets in space are presumably the so-called magnetars, the highly mag- 15 netized (with the strength of the ?eld of about 10 G) young neutron stars formed in the supernova explosions. The energy of magnetic ?elds is accumulated in astrophysical plasma, and the sudden release of this energy – an original electrodynamical ‘burst’ or‘explosion’–takesplaceunderde?nitebutquitegeneralconditions(P- att, 1992; Sturrock, 1994; Kivelson and Russell, 1995; Rose, 1998; Priest and Forbes, 2000; Somov, 2000; Kundt, 2001). Such a ‘?are’ in ast- physical plasma is accompanied by fast directed ejections (jets) of plasma, powerful ?ows of heat and hard electromagnetic radiation as well as by impulsive acceleration of charged particles to high energies. |
Contents
| 12 | |
| 19 | |
WeaklyCoupled Systems with Binary Collisions | 35 |
Propagation of Fast Particles in Plasma | 55 |
Motion of a Charged Particle in Given Fields | 79 |
Adiabatic Invariants in Astrophysical Plasma | 103 |
WaveParticle Interaction in Astrophysical Plasma | 115 |
Coulomb Collisions in Astrophysical Plasma | 133 |
Solartype Flares in Laboratory and Space | 193 |
Particle Acceleration in Current Layers | 211 |
Structural Instability of Reconnecting Current Layers | 237 |
93 | 264 |
Tearing Instability of Reconnecting Current Layers | 269 |
297 | 297 |
305 | 305 |
310 | 310 |
Macroscopic Description of Astrophysical Plasma | 163 |
MultiFluid Models of Astrophysical Plasma | 183 |
The Generalized Ohms Law in Plasma | 193 |
SingleFluid Models for Astrophysical Plasma | 205 |
Magnetohydrodynamics in Astrophysics | 223 |
Plasma Flows in a Strong Magnetic Field | 243 |
MHD Waves in Astrophysical Plasma | 263 |
Discontinuous Flows in a MHD Medium | 277 |
Evolutionarity of MHD Discontinuities | 305 |
Particle Acceleration by Shock Waves | 327 |
Stationary Flows in a Magnetic Field | 367 |
Notation | 393 |
Constants | 403 |
Bibliography | 405 |
Index | 426 |
Contents | vii |
10 | 1 |
Magnetic Reconnection 5 | 5 |
11 | 11 |
Reconnection in WeaklyIonized Plasma | 13 |
Reconnection in a Strong Magnetic Field 21 | 21 |
Evidence of Reconnection in Solar Flares | 47 |
The Bastille Day 2000 Flare | 77 |
Electric Currents Related to Reconnection | 99 |
77 | 147 |
Common terms and phrases
acceleration active approximation assume astrophysical average boundary Chapter charge collisional collisions component conductivity consider corona corresponds Coulomb current layer definition density depends derivative described determined direction discontinuity disk dissipation distribution function drift effect electric field electrons energy equal equation example Exercise field lines Figure flare flow flux force formula given gives heating Hence important increase initial inside instability integral interaction ions kind kinetic linear magnetic field mass mean mechanism momentum motion moving neutral observed obtain parallel parameter particles perturbation phase photospheric physical plane plasma potential pressure problem reconnection region result separator shock shown shows side solar solar flares solution Somov space stars strong structure surface temperature term theory thermal tion trap turbulence vector velocity waves