Dynamics of small-scale convective motions

Lemmerer, Birgit; Hanslmeier, A.; Muthsam, H.; Piantschitsch, Isabell

doi:10.1051/0004-6361/201528011

Cited by 11 publications

(12 citation statements)

References 40 publications

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“…The present RHD model has already revealed rotating plasma jets (Lemmerer et al. 2016 ), which seem to be triggered by turbulent convection. Our current investigations (Lemmerer et al.…”

Section: Introductionsupporting

confidence: 51%

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Structure of the solar photosphere studied from the radiation hydrodynamics code ANTARES

Leitner

Lemmerer

Hanslmeier

et al. 2017

Astrophys Space Sci

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The ANTARES radiation hydrodynamics code is capable of simulating the solar granulation in detail unequaled by direct observation. We introduce a state-of-the-art numerical tool to the solar physics community and demonstrate its applicability to model the solar granulation. The code is based on the weighted essentially non-oscillatory finite volume method and by its implementation of local mesh refinement is also capable of simulating turbulent fluids. While the ANTARES code already provides promising insights into small-scale dynamical processes occurring in the quiet-Sun photosphere, it will soon be capable of modeling the latter in the scope of radiation magnetohydrodynamics. In this first preliminary study we focus on the vertical photospheric stratification by examining a 3-D model photosphere with an evolution time much larger than the dynamical timescales of the solar granulation and of particular large horizontal extent corresponding to on the solar surface to smooth out horizontal spatial inhomogeneities separately for up- and downflows. The highly resolved Cartesian grid thereby covers of the upper convection zone and the adjacent photosphere. Correlation analysis, both local and two-point, provides a suitable means to probe the photospheric structure and thereby to identify several layers of characteristic dynamics: The thermal convection zone is found to reach some ten kilometers above the solar surface, while convectively overshooting gas penetrates even higher into the low photosphere. An wide transition layer separates the convective from the oscillatory layers in the higher photosphere.

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“…The present RHD model has already revealed rotating plasma jets (Lemmerer et al. 2016 ), which seem to be triggered by turbulent convection. Our current investigations (Lemmerer et al.…”

Section: Introductionsupporting

confidence: 51%

“…Our current investigations (Lemmerer et al. 2016 ) suggest that horizontal flows around rotating jets may trigger MHD kink waves (e.g. Zaqarashvili et al.…”

Section: Introductionmentioning

confidence: 68%

Structure of the solar photosphere studied from the radiation hydrodynamics code ANTARES

Leitner

Lemmerer

Hanslmeier

et al. 2017

Astrophys Space Sci

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“…In stellar physics fractal fingerprints in statistical observables (power law distributed) have been found in perimeter/area correlations (Roudier & Muller 1986) and size and lifetime distributions of solar granules (Lemmerer et al 2017), in sunspot number and area variability (Zhou et al 2014;Drozdz & Oswiecimka 2015), in magnetospheric substorms, auroras and flares (Aschwanden 2012), and finally in light curves from pulsating stars (Pascual-Granado 2011; De Freitas et al 2013, 2016. The generalization of the concept of fractal from geometrical objects to time series, lead to the property of Self-Affinity: a time series y(t) is self-affine if it has the following inhomogeneous scaling relation (Malamud & Turcotte 1999):…”

Section: Stellar Light Curves As Self-affine Time Seriesmentioning

confidence: 99%

Fractal analysis applied to light curves of δ Scuti stars★

Franciscis

Pascual-Granado

Suárez

et al. 2018

Monthly Notices of the Royal Astronomical Society

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Fractal behaviour, i.e. scale invariance in spatio-temporal dynamics, have been found to describe and model many systems in nature, in particular fluid mechanics and geophysical related geometrical objects, like the convective boundary layer of cumulus cloud fields, topographic landscapes, solar granulation patterns, and observational astrophysical time series, like light curves of pulsating stars.The main interest in the study of fractal properties in such physical phenomena lies in the close relationships they have with chaotic and turbulent dynamic.In this work we introduce some statistical tools for fractal analysis of light curves: Rescaled Range Analysis (R/S), Multifractal Spectra Analysis, and Coarse Graining Spectral Analysis (CGSA), an FFT based algorithm, which can discriminate in a time series the stochastic fractal power spectra from the harmonic one.An interesting application of fractal analysis in asteroseismology concerns the joint use of all these tools in order to develop classification criteria and algorithms for δ-Scuti pulsating stars. In fact from the fractal and multi-fractal fingerprints in background noise of light curves we could infer on different mechanism of stellar dynamic, among them rotation, modes excitation and magnetic activity.

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“…At the end of a granule's lifetime, a granule can fade away or it can fragment. Lemmerer et al (2017) show that the majority of granules fragment into two or more child granules. We give each simulated granule a 70% chance of fragmenting into exactly two children.…”

Section: Introductionmentioning

confidence: 97%

Characterizing the Motion of Solar Magnetic Bright Points at High Resolution

Kooten

Cranmer

2017

ApJ

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Magnetic bright points in the solar photosphere, visible in both continuum and G-band images, indicate footpoints of kilogauss magnetic flux tubes extending to the corona. The power spectrum of bright-point motion is thus also the power spectrum of Alfvén wave excitation, transporting energy up flux tubes into the corona. This spectrum is a key input in coronal and heliospheric models. We produce a power spectrum of bright-point motion using radiative magnetohydrodynamic simulations, exploiting spatial resolution higher than can be obtained in present-day observations, while using automated tracking to produce large data quantities. We find slightly higher amounts of power at all frequencies compared to observation-based spectra, while confirming the spectrum shape of recent observations. This also provides a prediction for observations of bright points with DKIST, which will achieve similar resolution and high sensitivity. We also find a granule size distribution in support of an observed twopopulation distribution, and we present results from tracking passive tracers which show a similar power spectrum to that of bright points. Finally, we introduce a simplified, laminar model of granulation, with which we explore the roles of turbulence and of the properties of the granulation pattern in determining bright-point motion.From these MURaM simulations, we extracted granule size distributions, the motion paths of passive tracers, and the motion paths of automatically-identified bright points. This

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Dynamics of small-scale convective motions

Cited by 11 publications

References 40 publications

Structure of the solar photosphere studied from the radiation hydrodynamics code ANTARES

Structure of the solar photosphere studied from the radiation hydrodynamics code ANTARES

Fractal analysis applied to light curves of δ Scuti stars★

Characterizing the Motion of Solar Magnetic Bright Points at High Resolution

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