Convective core entrainment in 1D main-sequence stellar models

Scott, Laura J. A.; Hirschi, Raphaël; Georgy, Cyril; Arnett, W. David; Meakin, Casey; Kaiser, Etienne A.; Ekström, Sylvia; Yusof, Norimah

doi:10.1093/mnras/stab752

Cited by 53 publications

(59 citation statements)

References 39 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This is an important aspect if the results of entrainment studies from hydrodynamic simulations are to be used in 1D calculations. Recently, the Bulk-Richardson entrainment scaling was applied to stellar evolution calculations (Staritsin 2013;Scott et al 2021). Scott et al (2021) show that it naturally leads to a mass-dependent efficiency of CBM, which is suggested by observations.…”

Section: Discussionmentioning

confidence: 97%

“…Recently, the Bulk-Richardson entrainment scaling was applied to stellar evolution calculations (Staritsin 2013;Scott et al 2021). Scott et al (2021) show that it naturally leads to a mass-dependent efficiency of CBM, which is suggested by observations. However, their study indicates that values of n < 1 result in a too efficient mixing and that the values for A that are commonly found in hydrodynamic simulations are too large.…”

Section: Discussionmentioning

confidence: 97%

“…Instead, it is best to use theoretical prescriptions like the entrainment law. Recently, 1D stellar evolution models using the entrainment law on the main-sequence have been computed by Scott et al (2021) and better reproduce the mass dependence of the main-sequence width. New 1D models during other phases of stellar evolution will be needed to assess the ability of the entrainment law to represent convective boundary mixing in 1D models throughout stellar evolution.…”

Section: Convective Boundary Mixingmentioning

confidence: 99%

See 2 more Smart Citations

Multidimensional low-Mach number time-implicit hydrodynamic simulations of convective helium shell burning in a massive star

Horst

Hirschi

Edelmann

et al. 2021

A&A

View full text Add to dashboard Cite

Context.A realistic parametrization of convection and convective boundary mixing in conventional stellar evolution codes is still the subject of ongoing research. To improve the current situation, multidimensional hydrodynamic simulations are used to study convection in stellar interiors. Such simulations are numerically challenging, especially for flows at low Mach numbers which are typical for convection during early evolutionary stages. Aims. We explore the benefits of using a low-Mach hydrodynamic flux solver and demonstrate its usability for simulations in the astrophysical context. Simulations of convection for a realistic stellar profile are analyzed regarding the properties of convective boundary mixing. Methods. The time-implicit Seven-League Hydro (SLH) code was used to perform multidimensional simulations of convective helium shell burning based on a 25 M⊙ star model. The results obtained with the low-Mach AUSM + -up solver were compared to results when using its non low-Mach variant AUSM + B -up. We applied well-balancing of the gravitational source term to maintain the initial hydrostatic background stratification. The computational grids have resolutions ranging from 180 × 90 2 to 810 × 540 2 cells and the nuclear energy release was boosted by factors of 3 × 10 3 , 1 × 10 4 , and 3 × 10 4 to study the dependence of the results on these parameters. Results. The boosted energy input results in convection at Mach numbers in the range of 10 −3 to 10 −2 . Standard mixing-length theory (MLT) predicts convective velocities of about 1.6 × 10 −4 if no boosting is applied. The simulations with AUSM + -up show a Kolmogorov-like inertial range in the kinetic energy spectrum that extends further toward smaller scales compared with its non low-Mach variant. The kinetic energy dissipation of the AUSM + -up solver already converges at a lower resolution compared to AUSM + B -up. The extracted entrainment rates at the boundaries of the convection zone are well represented by the bulk Richardson entrainment law and the corresponding fitting parameters are in agreement with published results for carbon shell burning. However, our study needs to be validated by simulations at higher resolution. Further, we find that a general increase in the entropy in the convection zone may significantly contribute to the measured entrainment of the top boundary. Conclusion.This study demonstrates the successful application of the AUSM + -up solver to a realistic astrophysical setup. Compressible simulations of convection in early phases at nominal stellar luminosity will benefit from its low-Mach capabilities. Similar to other studies, our extrapolated entrainment rate for the helium-burning shell would lead to an unrealistic growth of the convection zone if it is applied over the lifetime of the zone. Studies at nominal stellar luminosities and different phases of the same convection zone are needed to detect a possible evolution of the entrainment rate and the impact of radiation on convective boundary mixing.

show abstract

Section: Discussionmentioning

confidence: 97%

Section: Discussionmentioning

confidence: 97%

Section: Convective Boundary Mixingmentioning

confidence: 99%

See 1 more Smart Citation

Multidimensional low-Mach number time-implicit hydrodynamic simulations of convective helium shell burning in a massive star

Horst

Hirschi

Edelmann

et al. 2021

A&A

View full text Add to dashboard Cite

show abstract

“…This reduction of the core size in turn reduces the luminosity increase of the model during the main sequence. Recently, Scott et al (2021) presented a grid of models, with mass ranging between 1.5 and 60 M ⊙ , computed with the entrainment law and compared them to similar models computed with a penetrative overshoot. They find that the entrainment CBM scheme leads to a natural increase of the mixed region with mass, improving agreement with the observational constraints derived by Castro et al (2014).…”

Section: Convectionmentioning

confidence: 99%

“…In contrast with Staritsin (2013), they obtain an entrained mass that increases with time. This difference is due to the difference in the implementation: Staritsin (2013) scales the instantaneous entrained distance with the Richardson number (d ent = V ent t), while Scott et al (2021), following Cristini et al (2019), scale the mass entrainment rate (Ṁ ent ) with Ri B , building a cumulative entrainment. Note that while the cumulative implementation reproduces the trend seen in the hydro simulation, it is not clear how the secular evolution differs from the evolution on a dynamical timescale probed by 3D modeling.…”

Section: Convectionmentioning

confidence: 99%

Massive Star Modeling and Nucleosynthesis

Ekström

2021

Front. Astron. Space Sci.

View full text Add to dashboard Cite

After a brief introduction to stellar modeling, the main lines of massive star evolution are reviewed, with a focus on the nuclear reactions from which the star gets the needed energy to counterbalance its gravity. The different burning phases are described, as well as the structural impact they have on the star. Some general effects on stellar evolution of uncertainties in the reaction rates are presented, with more precise examples taken from the uncertainties of the 12C(α, γ)16O reaction and the sensitivity of the s-process on many rates. The changes in the evolution of massive stars brought by low or zero metallicity are reviewed. The impact of convection, rotation, mass loss, and binarity on massive star evolution is reviewed, with a focus on the effect they have on the global nucleosynthetic products of the stars.

show abstract

Slow Neutron-Capture Process in Evolved Stars

Hirschi

2023

Handbook of Nuclear Physics

View full text Add to dashboard Cite

Convective core entrainment in 1D main-sequence stellar models

Cited by 53 publications

References 39 publications

Multidimensional low-Mach number time-implicit hydrodynamic simulations of convective helium shell burning in a massive star

Multidimensional low-Mach number time-implicit hydrodynamic simulations of convective helium shell burning in a massive star

Massive Star Modeling and Nucleosynthesis

Slow Neutron-Capture Process in Evolved Stars

Contact Info

Product

Resources

About