Documentation scienceplus.abes.fr version Bêta

À propos de : Estimating the nonstructural component of the helioseismic surface term using hydrodynamic simulations        

AttributsValeurs
type
Is Part Of
Subject
License
Title
  • Estimating the nonstructural component of the helioseismic surface term using hydrodynamic simulations
Date
has manifestation of work
related by
Author
Abstract
  • Context. As the amount of asteroseismic data available continues to grow, the inability to accurately model observed oscillation frequencies is becoming a critical problem for interpreting these frequencies. A major component of this problem is the modeling of the near-surface layers. Aims. Our aim is to develop a method to estimate the effect of the near-surface layers on oscillation frequencies. Methods. In the proposed method we numerically estimate eigenfunctions in 3D hydrodynamic simulations. We match those to the eigenfunctions calculated from the classic equations applied to the horizontal averages of the structure variables. We use this procedure to calculate the frequency perturbation resulting from the dynamical part of the interaction of the oscillations with near-surface convection. As the last step we scale the numbers to the Sun. To provide a qualitative test of our method we performed a series of simulations, calculated the perturbations using our procedure, and compared them to previously reported residuals relative to solar models. Results. We find that we can largely reproduce the observed frequency residuals without resorting to poorly justified theoretical models. We find that, while the calculations of Houdek et al. (2017, MNRAS, 464, L124) produce similar frequency perturbations, the density-pressure phase differences computed here do not match those of that work.
article type
publisher identifier
  • aa36530-19
Date Copyrighted
Rights
  • © J. Schou and A. C. Birch 2020
Rights Holder
  • J. Schou and A. C. Birch
is part of this journal
is primary topic of



Alternative Linked Data Documents: ODE     Content Formats:       RDF       ODATA       Microdata