Common Envelope Evolution on a Moving Mesh
DOI:
https://doi.org/10.17307/wsc.v1i1.306Palabras clave:
Hydrodynamics, Common Envelope Evolution, Binary StarsResumen
The common envelope phase in binary star systems is simulated using the 3-D moving-mesh hydrodynamic code MANGA. Improvements to MANGA to improve accuracy and computation time are discussed. Two open questions in the physics of common envelope evolution are investigated. The effects of tidal forces present before the onset of a common envelope phase are explored by comparing simulations in which the giant star is initialized with varying degrees of rotation. The role of hydrogen recombination energy is investigated by using two different equations of state, only one of which includes the effects of recombination. Rotation is shown to increase the final binary separation, while recombination energy decreases the separation. Future improvements to MANGA to capture additional physics present in common envelopes are discussed.Citas
Chamandy, L; Blackman, EG; Frank, A; Carroll-Nellenback, J; Zou, Y; Tu, Y. “How Drag Force Evolves in Global Common Envelope Simulations,” arXiv e-prints, 2019, p. arXiv:1908.06195. https://ui.adsabs.harvard.edu/abs/2019arXiv190806195C
Chang, P; Wadsley, J; Quinn, T. “A Moving Mesh Hydrodynamics Solver for ChaNGa,” accepted to MNRAS, 2017
De, S; MacLeod, M; Everson, RW; Antoni, A; Mandel, I; Ramirez-Ruiz, E. “Common Envelope Wind Tunnel: The Effects of Binary Mass Ratio and Implications for the Accretion-Driven Growth of LIGO Binary Black Holes,” arXiv e-prints, 2019, p. arXiv:1910.13333. https://ui.adsabs.harvard.edu/abs/2019arXiv191013333D
Gianninas, A; Dufour, P; Kilic, M; Brown, WR; Bergeron, P; Hermes, JJ. “Precise Atmospheric Parameters for the Shortest-period Binary White Dwarfs: Gravitational Waves, Metals, and Pulsations,” ApJ, v. 794, 2014, p. 35. https://ui.adsabs.harvard.edu/#abs/2014ApJ...794...35G
Glanz, H; Perets, HB. “Efficient common-envelope ejection through dust-driven winds,” MNRAS, v. 478, 2018, p. L12–L17. https://ui.adsabs.harvard.edu/abs/2018MNRAS.478L..12G
Ivanova, N. “Common envelope: progress and transients,” preprint (arXiv:1706.07580), 2017. http://adsabs.harvard.edu/abs/2017arXiv170607580I
—. “On the Use of Hydrogen Recombination Energy during Common Envelope Events,” ApJ, v. 858, 2018, p. L24. https://ui.adsabs.harvard.edu/abs/2018ApJ...858L..24I
Ivanova, N; Justham, S; Chen, X; De Marco, O; Fryer, CL; Gaburov, E; Ge, H; Glebbeek, E; Han, Z; Li, XD; Lu, G; Marsh, T; Podsiadlowski, P; Potter, A; Soker, N; Taam, R; Tauris, TM; van den Heuvel, EPJ; Webbink, RF. “Common envelope evolution: where we stand and how we can move forward,” A&A Rev., v. 21, 2013, p. 59. http://ukads.nottingham.ac.uk/abs/2013A%26ARv..21...59I
Jetley, P; Gioachin, F; Mendes, C; Kale, LV; Quinn, TR. “”massively parallel cosmological simulations with changa”,” Proceedings of IEEE International Parallel and Distributed Processing Symposium, 2008
Jetley, P; Wesolowski, F; Gioachin, F; Kale, LV; Quinn, TR. “”scaling hierarchical n-body simulations on gpu clus- ters”,” Proceedings of the 2010 ACM/IEEE International Conference for High Performance Computing, 2010
Lecoanet, D; McCourt, M; Quataert, E; Burns, KJ; Vasil, GM; Oishi, JS; Brown, BP; Stone, JM; O’Leary, RM. “A validated non-linear Kelvin-Helmholtz benchmark for numerical hydrodynamics,” MNRAS, v. 455, 2016, p. 4274–4288. http://adsabs.harvard.edu/abs/2016MNRAS.455.4274L
Livio, M; Soker, N. “The common envelope phase in the evolution of binary stars,” ApJ, v. 329, 1988, p. 764–779. http://adsabs.harvard.edu/abs/1988ApJ...329..764L
Lo ́pez-Ca ́mara, D; De Colle, F; Moreno Me ́ndez, E. “Self-regulating jets during the Com- mon Envelope phase,” preprint (arXiv:1806.11115), 2018, p. arXiv:1806.11115. https://ui.adsabs.harvard.edu/abs/2018arXiv180611115L
MacLeod, M; Antoni, A; Murguia-Berthier, A; Macias, P; Ramirez-Ruiz, E. “Common Envelope Wind Tunnel: Coef- ficients of Drag and Accretion in a Simplified Context for Studying Flows around Objects Embedded within Stellar Envelopes,” ApJ, v. 838, 2017, p. 56. https://ui.adsabs.harvard.edu/abs/2017ApJ...838...56M
MacLeod, M; Ostriker, EC; Stone, JM. “Runaway Coalescence at the Onset of Common Envelope Episodes,” ApJ, v. 863, 2018, p. 5. https://ui.adsabs.harvard.edu/#abs/2018ApJ...863....5M
Menon, H; Wesolowski, L; Zheng, G; Jetley, P; Kale, L; Quinn, T; Governato, F. “Adaptive techniques for clustered N-body cosmological simulations,” Computational Astrophysics and Cosmology, v. 2, 2015, p. 1. http://adsabs.harvard.edu/abs/2015ComAC...2....1M
Nandez, JLA; Ivanova, N; Lombardi, JC. “Recombination energy in double white dwarf formation,” MNRAS, v. 450, 2015, p. L39–L43. http://adsabs.harvard.edu/abs/2015MNRAS.450L..39N
Nelemans, G; Verbunt, F; Yungelson, LR; Portegies Zwart, SF. “Reconstructing the evolution of double helium white dwarfs: envelope loss without spiral-in,” A&A, v. 360, 2000, p. 1011–1018. http://adsabs.harvard.edu/abs/2000A%26A...360.1011N
Ohlmann, ST; Ro ̈pke, FK; Pakmor, R; Springel, V. “Hydrodynamic Moving-mesh Simulations of the Common Envelope Phase in Binary Stellar Systems,” ApJ, v. 816, 2016, p. L9. http://adsabs.harvard.edu/abs/2016ApJ...816L...9O
Passy, JC; De Marco, O; Fryer, CL; Herwig, F; Diehl, S; Oishi, JS; Mac Low, MM; Bryan, GL; Rockefeller, G. “Simulating the Common Envelope Phase of a Red Giant Using Smoothed-particle Hydrodynamics and Uniform- grid Codes,” ApJ, v. 744, 2012, p. 52. http://adsabs.harvard.edu/abs/2012ApJ...744...52P
Paxton, B; Bildsten, L; Dotter, A; Herwig, F; Lesaffre, P; Timmes, F. “Modules for Experiments in Stellar Astro- physics (MESA),” ApJS, v. 192, 2011, p. 3. http://adsabs.harvard.edu/abs/2011ApJS..192....3P
Paxton, B; Cantiello, M; Arras, P; Bildsten, L; Brown, EF; Dotter, A; Mankovich, C; Montgomery, MH; Stello, D; Timmes, FX; Townsend, R. “Modules for Experiments in Stellar Astrophysics (MESA): Planets, Oscillations, Rotation, and Massive Stars,” ApJS, v. 208, 2013, p. 4. http://adsabs.harvard.edu/abs/2013ApJS..208....4P
Paxton, B; Marchant, P; Schwab, J; Bauer, EB; Bildsten, L; Cantiello, M; Dessart, L; Farmer, R; Hu, H; Langer, N; Townsend, RHD; Townsley, DM; Timmes, FX. “Modules for Experiments in Stellar Astrophysics (MESA): Binaries, Pulsations, and Explosions,” ApJS, v. 220, 2015, p. 15. http://adsabs.harvard.edu/abs/2015ApJS..220...15P
Paxton, B; Schwab, J; Bauer, EB; Bildsten, L; Blinnikov, S; Duffell, P; Farmer, R; Goldberg, JA; Marchant, P; Sorokina, E; Thoul, A; Townsend, RHD; Timmes, FX. “Modules for Experiments in Stellar Astrophysics (MESA): Convective Boundaries, Element Diffusion, and Massive Star Explosions,” ApJS, v. 234(2), 2018, p. 34. https://ui.adsabs.harvard.edu/abs/2018ApJS..234...34P
Paxton, B; Smolec, R; Schwab, J; Gautschy, A; Bildsten, L; Cantiello, M; Dotter, A; Farmer, R; Goldberg, JA; Jermyn, AS; Kanbur, SM; Marchant, P; Thoul, A; Townsend, RHD; Wolf, WM; Zhang, M; Timmes, FX. “Modules for Experiments in Stellar Astrophysics (MESA): Pulsating Variable Stars, Rotation, Convective Boundaries, and Energy Conservation,” ApJS, v. 243(1), 2019, p. 10. https://ui.adsabs.harvard.edu/abs/2019ApJS..243...10P
Prust, LJ; Chang, P. “Common envelope evolution on a moving mesh,” MNRAS, v. 486(4), 2019, p. 5809–5818. https://ui.adsabs.harvard.edu/abs/2019MNRAS.486.5809P
Ricker, PM; Taam, RE. “An AMR Study of the Common-envelope Phase of Binary Evolution,” ApJ, v. 746, 2012, p. 74. http://adsabs.harvard.edu/abs/2012ApJ...746...74R
Sabach, E; Hillel, S; Schreier, R; Soker, N. “Energy transport by convection in the common envelope evolution,” MNRAS, v. 472, 2017, p. 4361–4367. https://ui.adsabs.harvard.edu/abs/2017MNRAS.472.4361S
Sandquist, EL; Taam, RE; Chen, X; Bodenheimer, P; Burkert, A. “Double Core Evolution. X. Through the Envelope Ejection Phase,” ApJ, v. 500, 1998, p. 909–922. http://ukads.nottingham.ac.uk/abs/1998ApJ...500..909S
Soker, N. “What Planetary Nebulae Can Tell Us about Planetary Systems,” ApJ, v. 460, 1996, p. L53. https://ui.adsabs.harvard.edu/#abs/1996ApJ...460L..53S
Soker, N; Grichener, A; Sabach, E. “Radiating the hydrogen recombination energy during common envelope evolution,” preprint (arXiv:1805.08543), 2018, p. arXiv:1805.08543. https://ui.adsabs.harvard.edu/abs/2018arXiv180508543S
Springel, V. “E pur si muove: Galilean-invariant cosmological hydrodynamical simulations on a moving mesh,” MN- RAS, v. 401, 2010, p. 791–851. http://adsabs.harvard.edu/abs/2010MNRAS.401..791S
Terman, JL; Taam, RE; Hernquist, L. “Double-core evolution. 5: Three-dimensional effects in the merger of a red giant with a dwarf companion,” ApJ, v. 422, 1994, p. 729–736. http://ukads.nottingham.ac.uk/abs/1994ApJ...422..729T
Toro, E. Riemann Solvers and Numerical Methods for Fluid Dynamics: A Practical Introduction, Springer Berlin Heidelberg, ISBN 9783540498346, 2009
Turk, MJ; Smith, BD; Oishi, JS; Skory, S; Skillman, SW; Abel, T; Norman, ML. “yt: A Multi-code Analysis Toolkit for Astrophysical Simulation Data,” The Astrophysical Journal Supplement Series, v. 192, 2011, p. 9. http://adsabs.harvard.edu/abs/2011ApJS..192....9T
Webbink, RF. “Double white dwarfs as progenitors of R Coronae Borealis stars and Type I supernovae,” ApJ, v. 277, 1984, p. 355–360. http://adsabs.harvard.edu/abs/1984ApJ...277..355W
Zhu, C; Pakmor, R; van Kerkwijk, MH; Chang, P. “Magnetized Moving Mesh Merger of a Carbon-Oxygen White Dwarf Binary,” ApJ, v. 806, 2015, p. L1. http://adsabs.harvard.edu/abs/2015ApJ...806L...1Z
Descargas
Publicado
Cómo citar
Número
Sección
Licencia
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.