Ion Dynamics in Steady Collisionless Driven Reconnection

Abstract

Steady collisionless driven reconnection in an open system is investigated by means of a new two-dimensional full-particle simulation. The reconnection rate is controlled by an external driving electric field. Ion-meandering motion plays an important role in ion dynamics which controls the spatial structures of ion quantities. Although the electric current is predominantly carried by electrons, the current layer has the half-width of the ion-meandering orbit scale because the density profile is controlled by massive-ion motion. Thus, the global dynamic behavior of reconnection is dominantly controlled by ion dynamics. An electrostatic field generated through the finite-Larmor-radius effect leads to electron acceleration in the equilibrium current direction in the ion-dissipation region and ion heating by intensifying meandering motion. Our results are in agreement with the recent experimental results of Yamada et al. [Phys. Plasmas 7, 1781 (2000)] and of Hus et al. [Phys. Rev. Lett. 84, 3859 (2000)].