TY - JOUR
T1 - The s process in rotating low-mass AGB stars
T2 - Nucleosynthesis calculations in models matching asteroseismic constraints
AU - Den Hartogh, J. W.
AU - Hirschi, R.
AU - Lugaro, M.
AU - Doherty, C. L.
AU - Battino, U.
AU - Herwig, F.
AU - Pignatari, M.
AU - Eggenberger, P.
N1 - Funding Information:
Acknowledgements. This work has been supported by the European Research Council (ERC-2012-St Grant 306901, ERC-2015-STG Nr. 677497, ERC-2016-CO Grant 724560), and the EU COST Action CA16117 (ChETEC). This work is part of the BRIDGCE UK Network is a UK-wide network established to Bridge Research in the different Disciplines related to the Galactic Chemical Evolution and nuclear astrophysics. We acknowledge significant support to NuGrid from NSF grant PHY-1430152 (JINA Center for the Evolution of the Elements) and STFC (through the University of Hull’s Consolidated Grant ST/R000840/1). RH acknowledges support from the World Premier International Research Centre Initiative (WPI Initiative), MEXT, Japan. We performed the MPPNP calculations on the Viper High Performance Computing facility of the University of Hull and acknowledge its support team. We thank the referee for her/his detailed comments that helped improve this paper.
Publisher Copyright:
© ESO 2019.
PY - 2019/9/1
Y1 - 2019/9/1
N2 - Aims. We investigate the s-process during the AGB phase of stellar models whose cores are enforced to rotate at rates consistent with asteroseismology observations of their progenitors and successors. Methods. We calculated new 2 M⊙ , Z = 0.01 models, rotating at 0, 125, and 250 km s-1 at the start of main sequence. An artificial, additional viscosity was added to enhance the transport of angular momentum in order to reduce the core rotation rates to be in agreement with asteroseismology observations. We compared rotation rates of our models with observed rotation rates during the MS up to the end of core He burning, and the white dwarf phase. Results. We present nucleosynthesis calculations for these rotating AGB models that were enforced to match the asteroseismic constraints on rotation rates of MS, RGB, He-burning, and WD stars. In particular, we calculated one model that matches the upper limit of observed rotation rates of core He-burning stars and we also included a model that rotates one order of magnitude faster than the upper limit of the observations. The s-process production in both of these models is comparable to that of non-rotating models. Conclusions. Slowing down the core rotation rate in stars to match the above mentioned asteroseismic constraints reduces the rotationally induced mixing processes to the point that they have no effect on the s-process nucleosynthesis. This result is independent of the initial rotation rate of the stellar evolution model. However, there are uncertainties remaining in the treatment of rotation in stellar evolution, which need to be reduced in order to confirm our conclusions, including the physical nature of our approach to reduce the core rotation rates of our models, and magnetic processes.
AB - Aims. We investigate the s-process during the AGB phase of stellar models whose cores are enforced to rotate at rates consistent with asteroseismology observations of their progenitors and successors. Methods. We calculated new 2 M⊙ , Z = 0.01 models, rotating at 0, 125, and 250 km s-1 at the start of main sequence. An artificial, additional viscosity was added to enhance the transport of angular momentum in order to reduce the core rotation rates to be in agreement with asteroseismology observations. We compared rotation rates of our models with observed rotation rates during the MS up to the end of core He burning, and the white dwarf phase. Results. We present nucleosynthesis calculations for these rotating AGB models that were enforced to match the asteroseismic constraints on rotation rates of MS, RGB, He-burning, and WD stars. In particular, we calculated one model that matches the upper limit of observed rotation rates of core He-burning stars and we also included a model that rotates one order of magnitude faster than the upper limit of the observations. The s-process production in both of these models is comparable to that of non-rotating models. Conclusions. Slowing down the core rotation rate in stars to match the above mentioned asteroseismic constraints reduces the rotationally induced mixing processes to the point that they have no effect on the s-process nucleosynthesis. This result is independent of the initial rotation rate of the stellar evolution model. However, there are uncertainties remaining in the treatment of rotation in stellar evolution, which need to be reduced in order to confirm our conclusions, including the physical nature of our approach to reduce the core rotation rates of our models, and magnetic processes.
KW - Stars: AGB and post-AGB
KW - Stars: evolution
KW - Stars: rotation
UR - http://www.scopus.com/inward/record.url?scp=85103740639&partnerID=8YFLogxK
U2 - 10.1051/0004-6361/201935476
DO - 10.1051/0004-6361/201935476
M3 - Article
AN - SCOPUS:85103740639
SN - 0004-6361
VL - 629
JO - Astronomy & Astrophysics
JF - Astronomy & Astrophysics
M1 - A123
ER -