Convection and differential rotation properties of G and K stars computed with the ASH code

Matt, Sean P.; Cao, Olivier Do; Brown, Benjamin; Brun, Allan Sacha

doi:10.1002/asna.201111624

Cited by 59 publications

(73 citation statements)

References 31 publications

(41 reference statements)

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“…We generally found that for simulations with Ro < 1, meridional circulations possess many cells in radius and/or latitude per hemisphere. Only for anti-solar differential rotation cases, is the meridional circulation uni-cellular Matt et al (2011). We also find that the amplitude decreases as the rotational influence is increased as shown on Figure 4 right panel.…”

Section: Differential Rotation and Meridional Circulation In Starssupporting

confidence: 57%

“…The ω-effect is a direct measure of the differential rotation ΔΩ established in the star. It is well known both theoretically and observationally that the differential rotation in the convective envelope of solar-type stars is directly connected to the star's rotation rate Ω 0 (Donahue et al(1996), Barnes et al(2005), Ballot et al (2007), Brown et al (2008), Küker et al(2011), Matt et al (2011), Augustson et al (2012), Gastine et al (2013)). However, the exact scaling exponent n r (i.e.…”

Section: Stellar Dynamo: Theoretical Conceptsmentioning

confidence: 98%

“…The general trend is that the Coriolis force modifies convection such as to establish a large scale differential rotation Ω(r, θ) (Brun & Rempel (2009)). Depending on the influence of the Coriolis force, usually mesured by the turbulent Rossby number Ro = ω conv /2Ω 0 ∼ v conv /2Ω 0 d, or a variant, with ω conv , v conv characteristic vorticity and velocity in the convection zone and d the convection zone depth, the resulting differential rotation can be anti-solar (high Ro > 1, with fast poles-slow equator), solar-like (0.2 < Ro < 0.9, with fast equator, slow poles and some constancy at mid latitude of the isocontours of Ω) or Jupiter-like (Ro < 0.1, with cylindrical profile with alternance of prograde and retrograde jets) Matt et al (2011). On Figure 3 we represent these different profiles in models for various masses (0.5, 0.7 and 1.1 Msol) that also include the coupling to a stably stratified radiative interior, thus possessing a tachocline Matt & Brun (2013).…”

Section: Differential Rotation and Meridional Circulation In Starsmentioning

confidence: 99%

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Rotation and magnetism of solar-like stars: from scaling laws to spot-dynamos

Brun¹

2013

Proc. IAU

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Abstract. The Sun is the archetype of magnetic star and its proximity coupled with very high accuracy observations has helped us understanding how solar-like stars (e.g with a convective envelope) redistribute angular momentum and generate a cyclic magnetic field. However most solar models have been so fine tuned that when they are applied to other solar-like stars the agreement with observations is not good enough. I will thus discuss, based on theoretical considerations and multi-D MHD stellar models, what can be considered as robust properties of solar-like star dynamics and magnetism and what is still speculative. I will derive scaling laws for differential rotation and magnetic energy as a function of stellar parameters, discuss recent results of stellar dynamo models and define the new concept of spot-dynamo, e.g. global dynamo that develops self-consistent magnetic buoyant structures that emerge at the surface.

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Section: Differential Rotation and Meridional Circulation In Starssupporting

confidence: 57%

Section: Stellar Dynamo: Theoretical Conceptsmentioning

confidence: 98%

Section: Differential Rotation and Meridional Circulation In Starsmentioning

confidence: 99%

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Rotation and magnetism of solar-like stars: from scaling laws to spot-dynamos

Brun¹

2013

Proc. IAU

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“…Such behavior is seen in both simulations of spherical domains and Cartesian domains at various levels of turbulence in both the ASH simulations (Brun & Palacios 2009;Matt et al 2011) and simulations carried out in Cartesian domains (Käpylä et al 2004), as well as in spherical segments (Käpylä et al 2011). We observe that this transition between solar-like and anti-solar-like differential rotations occurs within flows that have a Rossby number of nearly one.…”

Section: Scaling With Rotation and Massmentioning

confidence: 55%

“…The Rayleigh numbers at mid-convection zone are about 50 times the critical Rayleigh number (Jones et al 2009) for the Case A simulations and about 25 times for the Case B simulations. These levels of supercriticality are equivalent to ASH simulations of lower mass stars (e.g., Brown et al 2008;Matt et al 2011). The lower level of supercriticality in the 1.3 M simulations is primarily due to the stronger driving of the convection and larger superadiabatic gradient, both of which are in turn due to the higher luminosity and narrower convection zones of the higher mass F-type stars.…”

Section: Scaling Diffusion With Rotationmentioning

confidence: 61%

Convection and Differential Rotation in F-Type Stars

Augustson

Brown

Brun

et al. 2012

ApJ

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Differential rotation is a common feature of main-sequence spectral F-type stars. In seeking to make contact with observations and to provide a self-consistent picture of how differential rotation is achieved in the interiors of these stars, we use the three-dimensional anelastic spherical harmonic (ASH) code to simulate global-scale turbulent flows in 1.2 and 1.3 M F-type stars at varying rotation rates. The simulations are carried out in spherical shells that encompass most of the convection zone and a portion of the stably stratified radiative zone below it, allowing us to explore the effects of overshooting convection. We examine the scaling of the mean flows and thermal state with rotation rate and mass and link these scalings to fundamental parameters of the simulations. Indeed, we find that the differential rotation becomes much stronger with more rapid rotation and larger mass, scaling as ΔΩ ∝ M 3.9 Ω 0.6 0 . Accompanying the growing differential rotation is a significant latitudinal temperature contrast, with amplitudes of 1000 K or higher in the most rapidly rotating cases. This contrast in turn scales with mass and rotation rate as ΔT ∝ M 6.4 Ω 1.6 0 . On the other hand, the meridional circulations become much weaker with more rapid rotation and with higher mass, with their kinetic energy decreasing as KE MC ∝ M −1.2 Ω −0.8 0 . Additionally, three of our simulations exhibit a global-scale shear instability within their stable regions that persists for the duration of the simulations. The flow structures associated with the instabilities have a direct coupling to and impact on the flows within the convection zone.

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References

2013

Magnetic Processes in Astrophysics

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Convection and differential rotation properties of G and K stars computed with the ASH code

Cited by 59 publications

References 31 publications

Rotation and magnetism of solar-like stars: from scaling laws to spot-dynamos

Rotation and magnetism of solar-like stars: from scaling laws to spot-dynamos

Convection and Differential Rotation in F-Type Stars

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