Common Envelope Shaping of Planetary Nebulae. III. The Launching of Jets in Proto-Planetary Nebulae
Abstract: We compute successfully the launching of two magnetic winds from two circumbinary disks formed after a common envelope event. The launching is produced by the increase of magnetic pressure due to the collapse of the disks. The collapse is due to internal torques produced by a weak poloidal magnetic field. The first wind can be described as a wide jet, with an average mass-loss rate of $\sim 1.3 \times 10{-7}$ \Moy\ and a maximum radial velocity of $\sim 230$ \kms. The outflow has a half-opening angle of $\sim 20{\circ}$. Narrow jets are also formed intermittently with velocities up to 3,000 \kms, with mass-loss rates of $\sim 6 \times 10{-12} $ \Moy\ during short periods of time. The second wind can be described as a wide X-wind, with an average mass-loss rate of $\sim 1.68 \times 10{-7}$ \Moy\ and a velocity of $\sim 30$ \kms. A narrow jet is also formed with a velocity of 250 \kms, and a mass-loss rates of $\sim 10{-12} $ \Moy. The computed jets are used to provide inflow boundary conditions for simulations of proto-planetary nebulae. The wide jet evolves into a molecular collimated outflow within a few astronomical units, producing proto-planetary nebulae with bipolar, elongated shapes, whose kinetic energies reach $\sim 4 \times 10{45}$ erg at 1,000 years. Similarities with observed features in W43A, OH231.8+4.2, and Hen 3-1475 are discussed. The computed wide X-wind produces proto-planetary nebulae with slower expansion velocities, with bipolar and elliptical shapes, and possible starfish type and quadrupolar morphology.
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