# High-resolution imaging spectroscopy of two micro-pores and an arch   filament system in a small emerging-flux region

**Authors:** S. J. Gonz\'alez Manrique, N. Bello Gonz\'alez, C. Denker

arXiv: 1703.10140 · 2017-03-30

## TL;DR

This study uses high-resolution imaging spectroscopy to analyze the evolution of micro-pores and arch filament systems in a small emerging flux region, revealing details about magnetic flux emergence, decay, and associated plasma flows.

## Contribution

It provides detailed observations of the smallest emerging flux regions, including micro-pores and miniature arch filament systems, and characterizes their temporal evolution and plasma flow dynamics.

## Key findings

- Micro-pores decay rapidly over hours, indicating submergence of Ω-loops.
- Chromospheric flows show downward velocities near loop footpoints and upward at loop tops.
- Flux emergence and decay occur over approximately two days.

## Abstract

Aims. The purpose of this investigation is to characterize the temporal evolution of an emerging flux region, the associated photospheric and chromospheric flow fields, and the properties of the accompanying arch filament system. Methods. This study is based on imaging spectroscopy with the G\"ottingen Fabry-P\'erot Interferometer at the Vacuum Tower Telescope, on 2008 August 7. Cloud model (CM) inversions of line scans in the strong chromospheric absorption H$\alpha$ line yielded CM parameters, which describe the cool plasma contained in the arch filament system. Results. The observations cover the decay and convergence of two micro-pores with diameters of less than one arcsecond and provide decay rates for intensity and area. The photospheric horizontal flow speed is suppressed near the two micro-pores indicating that the magnetic field is sufficiently strong to affect the convective energy transport. The micro-pores are accompanied by an arch filament system, where small-scale loops connect two regions with H$\alpha$ line-core brightenings containing an emerging flux region with opposite polarities. The chromospheric velocity of the cloud material is predominantly directed downwards near the footpoints of the loops with velocities of up to 12 km/s, whereas loop tops show upward motions of about 3 km/s. Conclusions. Micro-pores are the smallest magnetic field concentrations leaving a photometric signature in the photosphere. In the observed case, they are accompanied by a miniature arch filament system indicative of newly emerging flux in the form of $\Omega$-loops. Flux emergence and decay take place on a time-scale of about two days, whereas the photometric decay of the micro-pores is much more rapid (a few hours), which is consistent with the incipient submergence of $\Omega$-loops. The results are representative for the smallest emerging flux regions still recognizable as such.

## Full text

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## Figures

22 figures with captions in the complete paper: https://tomesphere.com/paper/1703.10140/full.md

## References

85 references — full list in the complete paper: https://tomesphere.com/paper/1703.10140/full.md

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Source: https://tomesphere.com/paper/1703.10140