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Shun Takeuchi, Ken Ohsuga, Shin Mineshige, Clumpy Outflows from Supercritical Accretion Flow, Publications of the Astronomical Society of Japan, Volume 65, Issue 4, 25 August 2013, 88, https://doi.org/10.1093/pasj/65.4.88
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Abstract
A significant amount of matter in supercritical (or super-Eddington) accretion flow is blown away by radiation force, thus forming outflows; however, the properties of such radiation-driven outflows have been poorly understood. We have performed global two-dimensional radiaion-magnetohydrodynamic simulations of supercritical accretion flow onto a black hole with 10 or 10|$^{8} M_{\odot}$| in a large simulation box of 514 |$r_{\rm S} \times 514 r_{\rm S}$| (with |$r_{\rm S}$| being the Schwarzschild radius). We confirm that uncollimated outflows with velocities of 10 percent of the speed of light emerge from the innermost part of the accretion flow at a wide angle of 10|$^{\circ}$| –50|$^{\circ}$| from the disk rotation axis. Importantly, the outflows exhibit clumpy structures above heights of |$\sim 250 r_{\rm S}$|. The typical size of the clumps is |$\sim 10 r_{\rm S}$|, which corresponds to one optical depth, and their shapes are slightly elongated along the outflow direction. Since clumps start to form in the layer above which the (upward) radiation is superior in force to the (downward) gravity, the Rayleigh–Taylor instability seems to be a primary cause. In addition, a radiation-hydrodynamic instability, which arises when radiation funnels through a radiation-pressure-supported atmosphere, may also help to form clumps of one optical depth. A magnetic photon bubble instability does not seem to be essential, since a similar clumpy outflow structure is obtained in nonmagnetic radiation-hydrodynamic simulations. Since the spatial covering factor of the clumps is estimated to be |$\sim$| 0.3, and since they are marginally optically thick, they will explain at least some of the rapid light variations of active galactic nuclei. We further discuss a possibility of producing broad-line region clouds by the clumpy outflow.
