# Plasma flows and magnetic field interplay during the formation of a pore

**Authors:** I. Ermolli, A. Cristaldi, F. Giorgi, F. Giannattasio, M. Stangalini,, P. Romano, A. Tritschler, F. Zuccarello

arXiv: 1701.06440 · 2017-01-24

## TL;DR

This study investigates the dynamic interplay of plasma flows and magnetic fields during pore formation in an active region, combining high-resolution observations with numerical simulation insights.

## Contribution

It provides detailed observational analysis of pore formation, linking plasma motions and magnetic flux reorganization with numerical simulation comparisons.

## Key findings

- Pore forms in less than 1 hour in the leading region of the active region.
- Magnetic flux emergence and reorganization drive pore formation.
- Observed plasma flows and magnetic signatures align with recent numerical models.

## Abstract

We studied the formation of a pore in AR NOAA 11462. We analysed data obtained with the IBIS at the DST on April 17, 2012, consisting of full Stokes measurements of the Fe I 617.3 nm lines. Furthermore, we analysed SDO/HMI observations in the continuum and vector magnetograms derived from the Fe I 617.3 nm line data taken from April 15 to 19, 2012. We estimated the magnetic field strength and vector components and the LOS and horizontal motions in the photospheric region hosting the pore formation. We discuss our results in light of other observational studies and recent advances of numerical simulations. The pore formation occurs in less than 1 hour in the leading region of the AR. The evolution of the flux patch in the leading part of the AR is faster (< 12 hour) than the evolution (20-30 hour) of the more diffuse and smaller scale flux patches in the trailing region. During the pore formation, the ratio between magnetic and dark area decreases from 5 to 2. We observe strong downflows at the forming pore boundary and diverging proper motions of plasma in the vicinity of the evolving feature that are directed towards the forming pore. The average values and trends of the various quantities estimated in the AR are in agreement with results of former observational studies of steady pores and with their modelled counterparts, as seen in recent numerical simulations of a rising-tube process. The agreement with the outcomes of the numerical studies holds for both the signatures of the flux emergence process (e.g. appearance of small-scale mixed polarity patterns and elongated granules) and the evolution of the region. The processes driving the formation of the pore are identified with the emergence of a magnetic flux concentration and the subsequent reorganization of the emerged flux, by the combined effect of velocity and magnetic field, in and around the evolving structure.

## Full text

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## Figures

143 figures with captions in the complete paper: https://tomesphere.com/paper/1701.06440/full.md

## References

67 references — full list in the complete paper: https://tomesphere.com/paper/1701.06440/full.md

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Source: https://tomesphere.com/paper/1701.06440