Magnetic reconnection with null and X-points

Abstract

Null and X-points are not themselves directly important to magnetic reconnection because distinguishable field lines do not approach them closely. Even in a collision-free plasma, magnetic field lines that approach each other on a scale c/ωpe become indistinguishable during an evolution. What is important is the different regions of space that can be explored by magnetic field lines that pass in the vicinity of null and X-points. Traditional reconnection theories made the assumption that the reconnected magnetic flux must be dissipated or diffused by an electric field. This assumption is false in three dimensional systems because an ideal evolution can cause magnetic field lines that cover a large volume to approach each other within the indistinguishability scale c/ωpe. When the electron collision time τei is short compared to the evolution time of the magnetic field τev, the importance of c/ωpe is replaced by the resistive time scale τη=(η/μ0)L2 with L the system scale. The magnetic Reynolds number is Rmτη/τev is enormous in many reconnection problems of interest. Magnetic flux diffusion implies the current density required for reconnection to compete with evolution scales as Rm while flux mixing implies the required current density to compete scales as Rm.