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Nonlinear evolution of interplanetary Alfvénic fluctuations with convected structures
Author(s) -
Roberts D. Aaron,
Ghosh Sanjoy,
Goldstein Melvyn
Publication year - 1996
Publication title -
geophysical research letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.007
H-Index - 273
eISSN - 1944-8007
pISSN - 0094-8276
DOI - 10.1029/96gl00382
Subject(s) - physics , solar wind , magnetohydrodynamics , interplanetary spaceflight , isotropy , turbulence , interplanetary magnetic field , computational physics , alfvén wave , nonlinear system , geophysics , magnetic field , interplanetary medium , heliospheric current sheet , astrophysics , mechanics , optics , quantum mechanics
At least at solar minimum, many regions in slow solar wind near the heliospheric current sheet have very low Alfvénicity. Motivated by recent suggestions that the interaction of the waves with the observed striated density, temperature, and magnetic field structures in the low Alfvénicity regions causes the decay of outward dominance, we have used two‐ and three‐dimensional MHD codes to simulate such situations to determine the evolution. We find that outward propagating waves in the presence of structures become only slightly less Alfvénic (unlike observations), and that what were initially parallel propagating waves fairly rapidly become nearly isotropic with a self‐similar spectrum typical of turbulence (similar to observations). These simulations suggest that the low Aflvénicty regions must arise from some other cause, such as “microstreams” that are eradicated as they decrease the Alfvénic correlations.