TY - JOUR
T1 - RECOVERY from GIANT ERUPTIONS in VERY MASSIVE STARS
AU - Kashi, Amit
AU - Davidson, Kris
AU - Humphreys, Roberta M.
N1 - Publisher Copyright:
© 2016. The American Astronomical Society. All rights reserved..
PY - 2016/1/20
Y1 - 2016/1/20
N2 - We use a hydro-and-radiative-transfer code to explore the behavior of a very massive star (VMS) after a giant eruption - i.e., following a supernova impostor event. Beginning with reasonable models for evolved VMSs with masses of 80 Mo and 120 Mo, we simulate the change of state caused by a giant eruption via two methods that explicitly conserve total energy. (1) Synthetically removing outer layers of mass of a few Mo while reducing the energy of the inner layers. (2) Synthetically transferring energy from the core to the outer layers, an operation that automatically causes mass ejection. Our focus is on the aftermath, not the poorly understood eruption itself. Then, using a radiation-hydrodynamic code in 1D with realistic opacities and convection, the interior disequilibrium state is followed for about 200 years. Typically the star develops a ∼400 km s-1 wind with a mass loss rate that begins around 0.1 Mo yr-1 and gradually decreases. This outflow is driven by κ-mechanism radial pulsations. The 1D models have regular pulsations but 3D models will probably be more chaotic. In some cases a plateau in the mass-loss rate may persist about 200 years, while other cases are more like η Car which lost >10 Mo and then had an abnormal mass loss rate for more than a century after its eruption. In our model, the post-eruption outflow carried more mass than the initial eruption. These simulations constitute a useful preliminary reconnaissance for 3D models which will be far more difficult.
AB - We use a hydro-and-radiative-transfer code to explore the behavior of a very massive star (VMS) after a giant eruption - i.e., following a supernova impostor event. Beginning with reasonable models for evolved VMSs with masses of 80 Mo and 120 Mo, we simulate the change of state caused by a giant eruption via two methods that explicitly conserve total energy. (1) Synthetically removing outer layers of mass of a few Mo while reducing the energy of the inner layers. (2) Synthetically transferring energy from the core to the outer layers, an operation that automatically causes mass ejection. Our focus is on the aftermath, not the poorly understood eruption itself. Then, using a radiation-hydrodynamic code in 1D with realistic opacities and convection, the interior disequilibrium state is followed for about 200 years. Typically the star develops a ∼400 km s-1 wind with a mass loss rate that begins around 0.1 Mo yr-1 and gradually decreases. This outflow is driven by κ-mechanism radial pulsations. The 1D models have regular pulsations but 3D models will probably be more chaotic. In some cases a plateau in the mass-loss rate may persist about 200 years, while other cases are more like η Car which lost >10 Mo and then had an abnormal mass loss rate for more than a century after its eruption. In our model, the post-eruption outflow carried more mass than the initial eruption. These simulations constitute a useful preliminary reconnaissance for 3D models which will be far more difficult.
KW - hydrodynamics
KW - methods: numerical
KW - stars: evolution
KW - stars: mass-loss
KW - stars: variables: general
KW - stars: winds, outflows
UR - http://www.scopus.com/inward/record.url?scp=84955483655&partnerID=8YFLogxK
U2 - 10.3847/0004-637X/817/1/66
DO - 10.3847/0004-637X/817/1/66
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AN - SCOPUS:84955483655
SN - 0004-637X
VL - 817
JO - Astrophysical Journal
JF - Astrophysical Journal
IS - 1
M1 - 66
ER -