Evolution of Active Regions

Driel-Gesztelyi, L. van; Green, Lucie May

doi:10.1007/lrsp-2015-1

Cited by 231 publications

(131 citation statements)

References 244 publications

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“…Measuring the magnetic flux and thus the growth and decay rates is hampered by the low cadence (96 min), the varying noise level as a function of the heliocentric angle, the geometric foreshortening of the pixel area, the angle of the magnetic field lines (assumed to be perpendicular to the surface) with the line-of-sight (LOS), and the small number of pixels having a flux density of more than 20 G. Therefore, we conservatively report only the total unsigned magnetic flux of 2.2 × 10 20 Mx (the negative magnetic flux is 1.2 × 10 20 Mx) at 08:00 UT on 2008 August 7, which attains a maximum right at the time of the high-resolution GFPI observations. The flux contained in the EFR is slightly larger than the upper limit for ephemeral regions (see van Driel-Gesztelyi & Green 2015), that is, much too small to form larger pores or even sunspots. Even though the time resolution is too coarse to provide a growth rate for the magnetic field, our measurements agree with a rapid rise time (already significant changes between the first two magnetograms) and a much slower decay rate (total unsigned flux of 1.3 × 10 20 Mx at 22:24 UT on 2008 August 7).…”

Section: Temporal Evolution Of Micro-poresmentioning

confidence: 90%

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

Manrique

González

Denker

2017

A&A

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Context. Emerging flux regions mark the first stage in the accumulation of magnetic flux eventually leading to pores, sunspots, and (complex) active regions. These flux regions are highly dynamic, show a variety of fine structure, and in many cases live only for a short time (less than a day) before dissolving quickly into the ubiquitous quiet-Sun magnetic field. Aims. The purpose of this investigation is to characterize the temporal evolution of a minute emerging flux region, the associated photospheric and chromospheric flow fields, and the properties of the accompanying arch filament system. We aim to explore flux emergence and decay processes and investigate if they scale with structure size and magnetic flux contents. Methods. This study is based on imaging spectroscopy with the Göttingen Fabry-Pérot Interferometer at the Vacuum Tower Telescope, Observatorio del Teide, Tenerife, Spain on 2008 August 7. Photospheric horizontal proper motions were measured with Local Correlation Tracking using broadband images restored with multi-object multi-frame blind deconvolution. Cloud model (CM) inversions of line scans in the strong chromospheric absorption Hα λ656.28 nm line yielded CM parameters (Doppler velocity, Doppler width, optical thickness, and source function), which describe the cool plasma contained in the arch filament system. Results. The high-resolution 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 already sufficiently strong to affect the convective energy transport. The micro-pores are accompanied by a small arch filament system as seen in Hα, where small-scale loops connect two regions with Hα line-core brightenings containing an emerging flux region with opposite polarities. The Doppler width, optical thickness, and source function reach the largest values near the Hα line-core brightenings. 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 −1 , whereas loop tops show upward motions of about 3 km s −1 . Some of the loops exhibit signs of twisting motions along the loop axis. 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 Ω-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 Ω-loops. Considering lifetime and evolution timescales, impact on the surrounding photospheric proper motions, and flow speed of the chromospheric plasma at the loop tops and footpoints, the results are representative for the smallest emergin...

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Section: Temporal Evolution Of Micro-poresmentioning

confidence: 90%

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

Manrique

González

Denker

2017

A&A

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“…above the C-class) are produced as long as high magnetic flux density/strong magnetic field concentrations are present, and the overall flare production rate decreases sharply with decreasing flux density, while the rate of CME pro-duction shows a much slower decrease with time, ı.e. CMEs keep erupting from active regions well into their decay phase (van Driel-Gesztelyi & Green 2015). This is not surprising, as during the decay phase persistent flux cancellations along inversion lines occur (Green et al 2011).…”

Section: Emergence and Active Life Of Ar Magnetic Fieldsmentioning

confidence: 96%

“…By all available observational accounts, sunspots form as large-scale flux bundles emerge from the solar interior onto the surface (see reviews by Zwaan 1978Zwaan , 1985Fan 2004Fan , 2009Lites 2009;Cheung & Isobe 2014;van Driel-Gesztelyi & Green 2015). At the scale of photospheric granulation (L ⇠ 1 Mm), the emerging flux reaches the surface as predominantly horizontal fields within the centers of granules (e.g.…”

Section: The Subsurface Origin Of Active Region Magnetic Fieldsmentioning

confidence: 99%

“…For an extensive review of active region evolution (during the phase when they are visible at and above the photosphere), we encourage the reader to consult van Driel-Gesztelyi & Green (2015). For discussions of the detailed processes related to magnetic flux emergence, we refer the reader to reviews by Schmieder et al (2014) and Cheung & Isobe (2014).…”

Section: Emergence and Active Life Of Ar Magnetic Fieldsmentioning

confidence: 99%

“…The definition of what constitutes a solar active region has evolved as our un-derstanding of solar magnetism has progressed in the last century. As suggested by van Driel-Gesztelyi & Green (2015), a useful modern definition due to Kiepenheuer (1968) is '[the] totality of all observable phenomena preceding, accompanying and following the birth of sunspots'. Figure 1 shows a subset of such observations from NASA's Solar Dynamics Observatory.…”

Section: Introductionmentioning

confidence: 99%

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The Life Cycle of Active Region Magnetic Fields

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Driel‐Gesztelyi²,

Pillet³

et al. 2016

Space Sciences Series of ISSI

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Coronal Magnetic Structure of Earthbound CMEs and In Situ Comparison

et al. 2018

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Predicting the magnetic field within an Earth‐directed coronal mass ejection (CME) well before its arrival at Earth is one of the most important issues in space weather research. In this article, we compare the intrinsic flux rope type, that is, the CME orientation and handedness during eruption, with the in situ flux rope type for 20 CME events that have been uniquely linked from Sun to Earth through heliospheric imaging. Our study shows that the intrinsic flux rope type can be estimated for CMEs originating from different source regions using a combination of indirect proxies. We find that only 20% of the events studied match strictly between the intrinsic and in situ flux rope types. The percentage rises to 55% when intermediate cases (where the orientation at the Sun and/or in situ is close to 45°) are considered as a match. We also determine the change in the flux rope tilt angle between the Sun and Earth. For the majority of the cases, the rotation is several tens of degrees, while 35% of the events change by more than 90°. While occasionally the intrinsic flux rope type is a good proxy for the magnetic structure impacting Earth, our study highlights the importance of capturing the CME evolution for space weather forecasting purposes. Moreover, we emphasize that determination of the intrinsic flux rope type is a crucial input for CME forecasting models.

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Evolution of Active Regions

Cited by 231 publications

References 244 publications

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

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

The Life Cycle of Active Region Magnetic Fields

Coronal Magnetic Structure of Earthbound CMEs and In Situ Comparison

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