Continuous transition from fast magnetic reconnection to slow reconnection and change of the reconnection system structure
Abstract
This paper analytically investigates a series of two-dimensional MHD reconnection solutions over a wide variation of magnetic Reynolds number (Rem*). A new series of solutions explains a continuous transition from Petschek-like fast regime to a Sweet-Parker-like slow regime. The inflow region is obtained from a Grad-Shafranov analysis used by Nitta et al. 2002 and the outflow region from a shock-tube approximation used by Nitta 2004, 2006. A single X-point (Petschek-like) solution forms for a sufficiently small Rem*. As Rem* gradually increases, the solutions shifts to an X-O-X solution with a magnetic island between two X-points. When Rem* increases further, the island collapses to a new elongated current sheet with Y-points at both ends (Sweet-Parker-like). These reconnection structures expand self-similarly as time proceeds. As Rem* increases, the reconnection rate and the reducible fraction of the initial magnetic energy of the system decrease as power-law functions of Rem*.
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