scholarly journals New theory of stellar convection without the mixing-length parameter: new stellar atmosphere model

2018 ◽  
Vol 940 ◽  
pp. 012020
Author(s):  
Stefano Pasetto ◽  
Cesare Chiosi ◽  
Mark Cropper ◽  
Eva K. Grebel
Keyword(s):  
Stellar Atmosphere ◽  
Mixing Length ◽  
Stellar Convection ◽  
Atmosphere Model

scholarly journals A Spherical Non‐LTE Line‐blanketed Stellar Atmosphere Model of the Early B GiantεCanis Majoris

1998 ◽  
Vol 498 (2) ◽  
pp. 837-850 ◽  
Author(s):  
J. P. Aufdenberg ◽  
P. H. Hauschildt ◽  
S. N. Shore ◽  
E. Baron
Keyword(s):  
Stellar Atmosphere ◽  
Atmosphere Model

scholarly journals Test of a New Theory for Stellar Convection using Helioseismology

1993 ◽  
Vol 137 ◽  
pp. 63-65
Author(s):  
L. Paternó ◽  
R. Ventura ◽  
V.M. Canuto ◽  
I. Mazzitelli
Keyword(s):  
Reaction Rates ◽  
Turbulent Convection ◽  
Standard Theory ◽  
Evolutionary Models ◽  
Mixing Length ◽  
Surface Layers ◽  
Stellar Convection ◽  
The Standard Model ◽  
Convection Model ◽  
Mixing Length Theory

AbstractTwo evolutionary models of the Sun have been tested using helioseismological data. The two models use the same input micro-physics (nuclear reaction rates, opacity, equation of state) and the same numerical evolutionary code, but differ in the treatment of turbulent convection. The first model employs the standard mixing - length theory of convection, while the second one employs a new turbulent convection model which overcomes some basic inconsistencies of the standard theory of convection.The test rests on the calculation of p-mode eigenfrequencies and on the comparison with the helioseismological data.The comparison shows an overall improvement of the eigenfrequencies calculated with the new model with respect to those calculated with the standard model, although it appears that both models still suffer from inaccuracies especially in the treatment of the surface layers.

scholarly journals Theory of stellar convection: removing the mixing-length parameter

2014 ◽  
Vol 445 (4) ◽  
pp. 3592-3609 ◽  
Author(s):  
S. Pasetto ◽  
C. Chiosi ◽  
M. Cropper ◽  
E. K. Grebel
Keyword(s):  
Mixing Length ◽  
Stellar Convection

scholarly journals New models for the convective flux in stellar atmospheres

1996 ◽  
Vol 176 ◽  
pp. 557-564 ◽  
Author(s):  
F. Kupka
Keyword(s):  
Stellar Evolution ◽  
Stellar Atmosphere ◽  
Stellar Atmospheres ◽  
Turbulence Theory ◽  
Mixing Length ◽  
Convective Flux ◽  
The Past ◽  
New Models ◽  
F Stars ◽  
Mixing Length Theory

Over the past decades various forms of the mixing length theory (MLT) have been used to describe convection in stellar atmospheres. Recent advances in turbulence theory now allow for major improvements in modelling thermal convection. We review several models for convection which have been derived from turbulence theory, and describe one of them, the “CM model”, in detail. The CM model has been used in several stellar evolution and helioseismology codes during the last four years and has now been applied to model atmospheres. An overwiew comparing stellar atmosphere models based on the CM formulation with its MLT predecessors indicates improvements on model atmospheres for A and F stars.

scholarly journals A Model for Stellar Convection and Spectral Line Asymmetries

1990 ◽  
Vol 138 ◽  
pp. 417-420
Author(s):  
H. M. Antia
Keyword(s):  
Spectral Line ◽  
Stellar Disk ◽  
Doppler Velocity ◽  
Mixing Length ◽  
Linear Superposition ◽  
Convective Flux ◽  
Stellar Convection ◽  
Stellar Velocity ◽  
Intensity Fluctuations ◽  
Mixing Length Theory

A model for stellar convection zones based on linear convective modes using a nonlocal mixing length theory is developed to study the spectral line asymmetries and the line shifts resulting from convective motions in the stellar photospheric region. The amplitudes of these linear convective modes is estimated by requiring the convective flux due to a linear superposition of such modes to reproduce the convective flux in the mixing length model. To study the spectral line asymmetries the convective mode with the largest amplitude in the photospheric line formation region is chosen to represent the stellar velocity field and the accompanying intensity fluctuations. Synthetic spectral line profiles are obtained by summing locally symmetric profiles over the stellar disk according to the local Doppler velocity and intensity fluctuations. The resulting line bisector shapes and the line shifts are compared with observations for α-Cen B. It is found that while the simple model proposed here can explain either the line shifts or the line bisector shape reasonably well, it fails to explain both these characteristics simultaneously.

scholarly journals Viscosity, Thermal and Electrical Conductivities in Turbulent Convection

1981 ◽  
Vol 93 ◽  
pp. 280-280
Author(s):  
Wasaburo Unno ◽  
Tohru Nakano ◽  
Masa-aki Kondo
Keyword(s):  
Spectral Theory ◽  
Convection Zone ◽  
Turbulent Convection ◽  
Nonlinear Interactions ◽  
Mixing Length ◽  
Average Life ◽  
Representative Element ◽  
Stellar Convection ◽  
Electrical Conductivities

Turbulent diffusivities are often used for representing nonlinear interactions of turbulent elements on the motion of a larger scale. In turbulent convection, the average life of a representative element is substantially lengthened by bouyancy. Taking this effect into account, we calculate turbulent viscosities, thermal and electrical conductivities for Boussinesq fluids on the basis of a spectral theory of turbulent convection (Nakano, Fukushima, Unno, and Kondo, 1979). The effect of bouyancy results in the increase of turbulent diffusivities, compared with the case without bouyancy. We also propose the generalization of the method such that a stellar convection zone can be theoretically constructed without recourse to the mixing length.

scholarly journals New Theory of Stellar Convection without the mixing-length parameter: new stellar atmosphere models

2015 ◽  
Vol 11 (A29B) ◽  
pp. 154-155
Author(s):  
Stefano Pasetto ◽  
Cesare Chiosi ◽  
Mark Cropper
Keyword(s):  
Energy Transport ◽  
Surrounding Medium ◽  
Time Dependent ◽  
Length Scale ◽  
The Sun ◽  
Mixing Length ◽  
Local Pressure ◽  
Stellar Convection ◽  
Non Local ◽  
Stellar Models

AbstractStellar convection is customarily described by the mixing-length theory, which makes use of the mixing-length scale to express the convective flux, velocity, and temperature gradients of the convective elements and stellar medium. The mixing-length scale is taken to be proportional to the local pressure scale height, and the proportionality factor (the mixing-length parameter) must be determined by comparing the stellar models to some calibrator, usually the Sun. No strong arguments exist to suggest that the mixing-length parameter is the same in all stars and all evolutionary phases. Because of this, all stellar models in the literature are hampered by this basic uncertainty.In a recent paper (Pasettoet al.2014) we presented a new theory that does not require the mixing length parameter. Our self-consistent analytical formulation of stellar convection determines all the properties of stellar convection as a function of the physical behavior of the convective elements themselves and the surrounding medium. The new theory of stellar convection is formulated starting from a conventional solution of the Navier-Stokes/Euler equations, i.e. the Bernoulli equation for a perfect fluid, but expressed in a non-inertial reference frame co-moving with the convective elements. In our formalism, the motion of stellar convective cells inside convective-unstable layers is fully determined by a new system of equations for convection in a non-local and time-dependent formalism.We obtained an analytical, non-local, time-dependent solution for the convective energy transport that does not depend on any free parameter. The predictions of the new theory are compared with those from the standard mixing-length paradigm with positive results for atmosphere models of the Sun and all the stars in the Hertzsprung-Russell diagram.

scholarly journals Theory of stellar convection: removing the mixing-length parameter

2015 ◽  
Vol 11 (A29B) ◽  
pp. 608-613
Author(s):  
Stefano Pasetto ◽  
Cesare Chiosi ◽  
Mark Cropper ◽  
Eva K. Grebel
Keyword(s):  
Energy Transport ◽  
Surrounding Medium ◽  
Time Dependent ◽  
Length Scale ◽  
The Sun ◽  
Mixing Length ◽  
Local Pressure ◽  
Stellar Convection ◽  
Non Local ◽  
Stellar Models

AbstractStellar convection is customarily described by the mixing-length theory, which makes use of the mixing-length scale to express the convective flux, velocity, and temperature gradients of the convective elements and stellar medium. The mixing-length scale is taken to be proportional to the local pressure scale height, and the proportionality factor (the mixing-length parameter) must be determined by comparing the stellar models to some calibrator, usually the Sun. No strong arguments exist to suggest that the mixing-length parameter is the same in all stars and all evolutionary phases. Because of this, all stellar models in the literature are hampered by this basic uncertainty.In a recent paper (Pasettoet al.2014) we presented a new theory that does not require the mixing length parameter. Our self-consistent analytical formulation of stellar convection determines all the properties of stellar convection as a function of the physical behaviour of the convective elements themselves and the surrounding medium. The new theory of stellar convection is formulated starting from a conventional solution of the Navier-Stokes/Euler equations, i.e. the Bernoulli equation for a perfect fluid, but expressed in a non-inertial reference frame co-moving with the convective elements. In our formalism, the motion of stellar convective cells inside convective-unstable layers is fully determined by a new system of equations for convection in a non-local and time-dependent formalism.We obtained an analytical, non-local, time-dependent solution for the convective energy transport that does not depend on any free parameter. The predictions of the new theory are compared with those from the standard mixing-length paradigm with positive results for atmosphere models of the Sun and all the stars in the Hertzsprung-Russell diagram.

scholarly journals Pre-explosion Properties of Helium Star Donors to Thermonuclear Supernovae

2021 ◽  
Vol 922 (2) ◽  
pp. 241
Author(s):  
Tin Long Sunny Wong ◽  
Josiah Schwab ◽  
Ylva Götberg
Keyword(s):  
Stellar Evolution ◽  
White Dwarf ◽  
Stellar Atmosphere ◽  
Thermonuclear Supernovae ◽  
Atmosphere Model ◽  
Binary Evolution ◽  
Star Binary ◽  
Helium Star

Abstract Helium star–carbon-oxygen white dwarf (CO WD) binaries are potential single-degenerate progenitor systems of thermonuclear supernovae. Revisiting a set of binary evolution calculations using the stellar evolution code MESA, we refine our previous predictions about which systems can lead to a thermonuclear supernova and then characterize the properties of the helium star donor at the time of explosion. We convert these model properties to near-UV/optical magnitudes assuming a blackbody spectrum and support this approach using a matched stellar atmosphere model. These models will be valuable to compare with pre-explosion imaging for future supernovae, though we emphasize the observational difficulty of detecting extremely blue companions. The pre-explosion source detected in association with SN 2012Z has been interpreted as a helium star binary containing an initially ultra-massive WD in a multiday orbit. However, extending our binary models to initial CO WD masses of up to 1.2 M ⊙, we find that these systems undergo off-center carbon ignitions and thus are not expected to produce thermonuclear supernovae. This tension suggests that, if SN 2012Z is associated with a helium star–WD binary, then the pre-explosion optical light from the system must be significantly modified by the binary environment and/or the WD does not have a carbon-rich interior composition.

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