The forward‐reverse shock pair at large heliocentric distances

An unsteady one-dimensional MHD model is developed to study (1) the essential physical processes involved in the development of the forward-reverse shock pair at large heliocentric distances, (2) the interaction of the shock pair with the rarefaction regions of the stream structure, and (3) the merging of two forward or reverse shocks. We use a method of solution which is quite different from the finite difference methods: MHD shocks (or contact surfaces) are treated as boundary surfaces. The presence of moving shocks divides the domain of interest in the r-t plane into several flow regions. The jump conditions of MHD shocks describe the flow conditions across the moving boundaries between flow regions. The method of characteristics describes the variation of flow conditions in each region. The solutions explain the formation of the shock pair in the leading edge region as resulting from the merging of fast waves. The strong MHD disturbances generated in the corotating interaction region (CIR) propagate at a fast speed relative to the moving material. The wave propagation speed is greater in CIR than in its surroundings. This causes the disturbances in CIR to pile up to form a shock pair. During the formation process the shocks continuously grow into a fully developed state. The newly formed shock pair will then propagate outward from the leading edge to interact with the ambient rarefaction regions. The double-sawtooth configuration of the velocity profile is a result of this interaction. We also obtain solutions to demonstrate that the merging of two shocks produces a stronger shock and a contact surface on its backside.

[1]  L. Burlaga,et al.  Coalescence of two pressure waves associated with stream interactions. [in outer heliosphere , 1985 .

[2]  V. Pizzo Quasi-steady solar wind dynamics , 1983 .

[3]  L. Burlaga Corotating pressure waves without fast streams in the solar wind , 1983 .

[4]  H. Rosenbauer,et al.  Dynamical evolution of interplanetary magnetic fields and flows between 0.3 AU and 8.5 AU - Entrainment , 1983 .

[5]  L. Burlaga Corotating pressure waves without streams in the solar wind , 1983 .

[6]  Y. Whang,et al.  Magnetohydrodynamic interaction of high‐speed streams , 1981 .

[7]  V. Pizzo A three-dimensional model of co-rotating streams in the solar wind. 2: Hydrodynamic streams , 1979 .

[8]  S. Wu,et al.  Dynamic MHD modeling of solar wind corotating stream interaction regions observed by Pioneer 10 and 11 , 1978 .

[9]  G. Siscoe Three‐dimensional aspects of interplanetary shock waves , 1976 .

[10]  M. Dryer,et al.  MHD solution of interplanetary disturbances generated by simulated velocity perturbations. [coronal hole effects , 1976 .

[11]  A. Hundhausen,et al.  Solar wind stream evolution at large heliocentric distances: Experimental demonstration and the test of a model , 1976 .

[12]  A. Hundhausen,et al.  Solar wind structure at large heliocentric distances: An interpretation of Pioneer 10 observations , 1976 .

[13]  E. Smith,et al.  Observations of interaction regions and corotating shocks between one and five AU - Pioneers 10 and 11. [solar wind streams] , 1976 .

[14]  M. Dryer,et al.  Numerical MHD simulation of interplanetary shock pairs , 1975 .

[15]  A. Hundhausen Evolution of large‐scale solar wind structures beyond 1 AU , 1973 .

[16]  A. Hundhausen Nonlinear model of high‐speed solar wind streams , 1973 .

[17]  L. Burlaga A reverse hydromagnetic shock in the solar wind , 1970 .

[18]  D. Colburn,et al.  The SI+-SI− pair and interplanetary forward-reverse shock ensembles , 1965 .

[19]  A. Dessler,et al.  Interpretation of Kp index and M-region geomagnetic storms , 1963 .