Fast resistive reconnection regime in the nonlinear evolution of double tearing modes.

Phases of nonlinear double tearing modes are studied numerically. The first two phases lead to the formation and growth of magnetic islands and are followed by a fast reconnection phase to complete the process, driven by a process of neighboring magnetic separatrices merging and magnetic islands coupling. The fast growth can be understood as a result of the island interaction equivalent to a steadily inward flux boundary driven. Resistivity dependences for various phases are studied and shown by scaling analysis for the first time. It is found that after an early Sweet-Parker phase with a {eta}{sup 1/2}-scale, a slow nonlinear phase in a Rutherford regime with a {eta}{sup 1}-scale is followed by the fast reconnection phase with a {eta}{sup 1/5}-scale.