Transport of Internetwork Magnetic Flux Elements in the Solar Photosphere

The motions of small-scale magnetic flux elements in the solar photosphere can provide some measure of the Lagrangian properties of the convective flow. Measurements of these motions have been critical in estimating the turbulent diffusion coefficient in flux-transport dynamo models and in determini...

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Bibliographic Details
Published in:The Astrophysical journal 2018-02, Vol.854 (2), p.118
Main Authors: Agrawal, Piyush, Rast, Mark P., Gos̆i, Milan, Bellot Rubio, Luis R., Rempel, Matthias
Format: Article
Language:English
Subjects:
Advection
Alfven waves
Astrophysics
Center of gravity
Computational fluid dynamics
Computer simulation
Convective flow
Coronal heating
Diffusion
Diffusion coefficient
Displacement
Dynamo theory
Eddy diffusion
Excitation spectra
Fluctuations
Magnetic flux
Magnetohydrodynamics
Narrowband
Photosphere
Probability distribution
Scaling
Sun: granulation
Sun: photosphere
Transport
Turbulent diffusion
Wave excitation
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Summary:The motions of small-scale magnetic flux elements in the solar photosphere can provide some measure of the Lagrangian properties of the convective flow. Measurements of these motions have been critical in estimating the turbulent diffusion coefficient in flux-transport dynamo models and in determining the Alfvén wave excitation spectrum for coronal heating models. We examine the motions of internetwork flux elements in Hinode/Narrowband Filter Imager magnetograms and study the scaling of their mean squared displacement and the shape of their displacement probability distribution as a function of time. We find that the mean squared displacement scales super-diffusively with a slope of about 1.48. Super-diffusive scaling has been observed in other studies for temporal increments as small as 5 s, increments over which ballistic scaling would be expected. Using high-cadence MURaM simulations, we show that the observed super-diffusive scaling at short increments is a consequence of random changes in barycenter positions due to flux evolution. We also find that for long temporal increments, beyond granular lifetimes, the observed displacement distribution deviates from that expected for a diffusive process, evolving from Rayleigh to Gaussian. This change in distribution can be modeled analytically by accounting for supergranular advection along with granular motions. These results complicate the interpretation of magnetic element motions as strictly advective or diffusive on short and long timescales and suggest that measurements of magnetic element motions must be used with caution in turbulent diffusion or wave excitation models. We propose that passive tracer motions in measured photospheric flows may yield more robust transport statistics.
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/aaa251