Other
Scientific paper
Dec 2007
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2007agufmsm11a0309m&link_type=abstract
American Geophysical Union, Fall Meeting 2007, abstract #SM11A-0309
Other
2154 Planetary Bow Shocks, 2784 Solar Wind/Magnetosphere Interactions, 7846 Plasma Energization, 7851 Shock Waves (4455), 7867 Wave/Particle Interactions (2483, 6984)
Scientific paper
Both numerical simulations and experimental observations (CLUSTER) have evidenced that the front of quasi perpendicular shocks may be strongly stationary or nonstationary. Simulations have evidenced several different mechanisms responsible for this nonstationarity both on macro- (ion) and micro- scales and but no detailed comparison has been performed with experimental data until now. The fact that several mechanisms can coexist together make a clear diagnosis quite difficult. On the other hand, multi satellites CLUSTER mission reveals to be helpful for clarifying the situation. The present work focuses on experimental CLUSTER data where macroscale nonstationarity is evidenced and identified as being due to the shock front self reformation driven by the accumulation of reflected ions. Detailed analysis is performed based on many criteria accumulated from a collection of previous 1D and 2D PIC simulation (changes both in ramp-foot scales and typical changes in the local ion distribution function). In particular, it accounts the surprising experimental results where the shock ramp can be very thin and access to a few inertial electron lengths only. Present detailed results are also completed by an additional statistical analysis. These experimental data confirm that the shock front can be nonstationary and that the identified responsible process strongly competes with another self reformation process driven by nonlinear dispersive waves activity.
Dandouras Iannis
Horbury Tim S.
Lembege Bertand
Lucek Elisabeth A.
Mazelle Christian
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