Three-Dimensional Evolution of the Parker Instability under a Uniform Gravity

Using an isothermal MHD code, we have performed three-dimensional, highresolution simulations of the Parker instability. The initial equilibrium system is composed of exponentially-decreasing isothermal gas and magnetic field (along the azimuthal direction) under a uniform gravity. The evolution of the instability can be divided into three phases: linear, nonlinear, and relaxed. During the linear phase, the perturbations grow exponentially with a preferred scale along the azimuthal direction but with smallest possible scale along the radial direction, as predicted from linear analyses. During the nonlinear phase, the growth of the instability is saturated and flow motion becomes chaotic. Magnetic reconnection occurs, which allows gas to cross field lines. This, in turn, results in the redistribution of gas and magnetic field. The system approaches a new equilibrium in the relaxed phase, which is different from the one seen in two-dimensional works. The structures formed during the evolution are sheet-like or filamentary, whose shortest dimension is radial. Their maximum density enhancement factor relative to the initial value is less than 2. Since the radial dimension is too small and the density enhancement is too low, it is difficult to regard the Parker instability alone as a viable mechanism for the formation of giant molecular clouds. Subject headings: instabilities — ISM: clouds — ISM: magnetic fields — ISM: structure — MHD Korea Astronomy Observatory, San 36-1, Hwaam-Dong, Yusong-Ku, Taejon 305-348, Korea: [email protected] Department of Astronomy, Seoul National University, Seoul 151-742, Korea: [email protected] Department of Astronomy and Space Science, Chungnam National University, Taejon 305-764, Korea: [email protected] Department of Astronomy, University of Minnesota, Minneapolis, MN 55455: [email protected]