Your search keyword '"planetary nebulae: Common Envelope"' showing total 3 results

1. Planetary Nebulae Shaped by Common Envelope Evolution

Author

Adam Frank, Zhuo Chen, Thomas Reichardt, Orsola De Marco, Eric Blackman, and Jason Nordhaus

Subjects

post-AGB stars, pre-PN hydrodynamic models, planetary nebulae: Common Envelope, planetary nebulae: individual (OH231+8+04.2), Astronomy, QB1-991

Abstract

The morphologies of planetary nebula have long been believed to be due to wind shaping processes in which a “fast wind„ from the central star impacts a previously ejected envelope. It is assumed that asymmetries existing in the “slow wind„ envelope would lead to inertial confinement, shaping the resulting interacting wind flow. We present new results demonstrating the effectiveness of Common Envelope Evolution (CEE) at producing aspherical envelopes which, when impinged upon by a spherical fast stellar wind, produce highly bipolar, jet-like outflows. We have run two simple cases using the output of a single PHANTOM SPH CEE simulation. Our work uses the Adaptive Mesh Refinement code AstroBEAR to track the interaction of the fast wind and CEE ejecta allows us to follow the morphological evolution of the outflow lobes at high resolution in 3-D. Our two models bracket low and high momentum output fast winds. We find the interaction leads to highly collimated bipolar outflows. In addition, the bipolar morphology depends on the fast wind momentum injection rate. With this dependence comes the initiation of significant symmetry breaking between the top and bottom bipolar lobes. Our simulations, though simplified, confirm the long-standing belief that CEE can plan a major role in PPN and PN shaping. These simulations are intended as an initial exploration of the post-CE/PPN flow patterns that can be expected from central source outflows and CE ejecta.

Published

2018

2. Planetary Nebulae Shaped by Common Envelope Evolution

Author

Jason Nordhaus, Zhuo Chen, Adam Frank, Thomas Reichardt, Orsola De Marco, and Eric G. Blackman

Subjects

010504 meteorology & atmospheric sciences, lcsh:Astronomy, Astrophysics::High Energy Astrophysical Phenomena, FOS: Physical sciences, Astrophysics, 01 natural sciences, planetary nebulae: individual (OH231+8+04.2), lcsh:QB1-991, Common envelope, pre-PN hydrodynamic models, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, Symmetry breaking, Ejecta, 010303 astronomy & astrophysics, Solar and Stellar Astrophysics (astro-ph.SR), Astrophysics::Galaxy Astrophysics, 0105 earth and related environmental sciences, Envelope (waves), Physics, Momentum (technical analysis), Adaptive mesh refinement, Astronomy and Astrophysics, Planetary nebula, post-AGB stars, Astrophysics - Solar and Stellar Astrophysics, planetary nebulae: Common Envelope, Physics::Space Physics, Outflow, Astrophysics::Earth and Planetary Astrophysics

Abstract

The morphologies of planetary nebula have long been believed to be due to wind shaping processes in which a &ldquo, fast wind&rdquo, from the central star impacts a previously ejected envelope. It is assumed that asymmetries existing in the &ldquo, slow wind&rdquo, envelope would lead to inertial confinement, shaping the resulting interacting wind flow. We present new results demonstrating the effectiveness of Common Envelope Evolution (CEE) at producing aspherical envelopes which, when impinged upon by a spherical fast stellar wind, produce highly bipolar, jet-like outflows. We have run two simple cases using the output of a single PHANTOM SPH CEE simulation. Our work uses the Adaptive Mesh Refinement code AstroBEAR to track the interaction of the fast wind and CEE ejecta allows us to follow the morphological evolution of the outflow lobes at high resolution in 3-D. Our two models bracket low and high momentum output fast winds. We find the interaction leads to highly collimated bipolar outflows. In addition, the bipolar morphology depends on the fast wind momentum injection rate. With this dependence comes the initiation of significant symmetry breaking between the top and bottom bipolar lobes. Our simulations, though simplified, confirm the long-standing belief that CEE can plan a major role in PPN and PN shaping. These simulations are intended as an initial exploration of the post-CE/PPN flow patterns that can be expected from central source outflows and CE ejecta.

Published

2018

3. Planetary Nebulae Shaped by Common Envelope Evolution.

Author

Frank, Adam, Chen, Zhuo, Reichardt, Thomas, De Marco, Orsola, Blackman, Eric, and Nordhaus, Jason

Subjects

PLANETARY nebulae, STELLAR winds, ASYMPTOTIC giant branch stars, BIPOLAR outflows (Astrophysics), COMPUTER simulation

Abstract

The morphologies of planetary nebula have long been believed to be due to wind shaping processes in which a "fast wind" from the central star impacts a previously ejected envelope. It is assumed that asymmetries existing in the "slow wind" envelope would lead to inertial confinement, shaping the resulting interacting wind flow. We present new results demonstrating the effectiveness of Common Envelope Evolution (CEE) at producing aspherical envelopes which, when impinged upon by a spherical fast stellar wind, produce highly bipolar, jet-like outflows. We have run two simple cases using the output of a single PHANTOM SPH CEE simulation. Our work uses the Adaptive Mesh Refinement code AstroBEAR to track the interaction of the fast wind and CEE ejecta allows us to follow the morphological evolution of the outflow lobes at high resolution in 3-D. Our two models bracket low and high momentum output fast winds. We find the interaction leads to highly collimated bipolar outflows. In addition, the bipolar morphology depends on the fast wind momentum injection rate. With this dependence comes the initiation of significant symmetry breaking between the top and bottom bipolar lobes. Our simulations, though simplified, confirm the long-standing belief that CEE can plan a major role in PPN and PN shaping. These simulations are intended as an initial exploration of the post-CE/PPN flow patterns that can be expected from central source outflows and CE ejecta. [ABSTRACT FROM AUTHOR]

Published

2018