Magnetic and velocity fields of a solar pore

Sobotka, M.; Moro, D. Del; Jurčák, J.; Berrilli, F.

doi:10.1051/0004-6361/201117851

Cited by 23 publications

(43 citation statements)

References 38 publications

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“…Concentric running waves propagate through the filamentary structure with the speed of sound and the observed characteristics of acoustic oscillations correspond to those in a superpenumbra. Although a strong horizontal magnetic field responsible for the formation of a penumbra is missing in the pore, the magnetic field of B 1500 G at the pore's border inclined by 40 • (Sobotka et al 2012) manifests itself in the middle photosphere by short bright filaments seen A84, page 12 of 14 in the Ca II line wings (Fig. 1b) and its field lines, which return to opposite-polarity patches dispersed in the photosphere around the pore, very probably form the filamentary structure with superpenumbral characteristics in the chromosphere.…”

Section: Discussionmentioning

confidence: 99%

“…Short bright filaments surround the pore's edge. These filaments are a manifestation of an inclined magnetic field that extends beyond the pore's visible boundary in the form of spines (Sobotka et al 2012).…”

Section: Morphologymentioning

confidence: 99%

“…This is caused by the more inclined magnetic field in the large eastern umbral core, which expands faster above the LB than the almost vertical magnetic field from the smaller core. In Sobotka et al (2012) we determined the magnetic-field inclination and azimuth in the LB from inversions of Stokes profiles of Fe I 617.33 nm, observed simultaneously with the Ca II line. The azimuth direction is perpendicular to the LB axis.…”

Section: Structure and Widthmentioning

confidence: 99%

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Dynamics of the solar atmosphere above a pore with a light bridge

Sobotka

Švanda

Jurčák

et al. 2013

A&A

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Context. Solar pores are small sunspots lacking a penumbra that have a prevailing vertical magnetic-field component. They can include light bridges at places with locally reduced magnetic field. Like sunspots, they exhibit a wide range of oscillatory phenomena. Aims. A large isolated pore with a light bridge (NOAA 11005) is studied to obtain characteristics of a chromospheric filamentary structure around the pore, to analyse oscillations and waves in and around the pore, and to understand the structure and brightness of the light bridge. Methods. Spectral imaging observations in the line Ca II 854.2 nm and complementary spectropolarimetry in Fe I lines, obtained with the DST/IBIS spectrometer and HINODE/SOT spectropolarimeter, were used to measure photospheric and chromospheric velocity fields, oscillations, waves, the magnetic field in the photosphere, and acoustic energy flux and radiative losses in the chromosphere. Results. The chromospheric filamentary structure around the pore has all important characteristics of a superpenumbra: it shows an inverse Evershed effect and running waves, and has a similar morphology and oscillation character. The granular structure of the light bridge in the upper photosphere can be explained by radiative heating. Acoustic waves leaking up from the photosphere along the inclined magnetic field in the light bridge transfer enough energy flux to balance the entire radiative losses of the light-bridge chromosphere. Conclusions. A penumbra is not a necessary condition for the formation of a superpenumbra. The light bridge is heated by radiation in the photosphere and by acoustic waves in the chromosphere.

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Section: Discussionmentioning

confidence: 99%

Section: Morphologymentioning

confidence: 99%

Section: Structure and Widthmentioning

confidence: 99%

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Dynamics of the solar atmosphere above a pore with a light bridge

Sobotka

Švanda

Jurčák

et al. 2013

A&A

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“…Much of the flux in ARs that is not in the form of sunspots is organized in magnetic concentrations (much) smaller than spots, either in the form of pores or, most commonly, magnetic elements. Magnetic pores, sunspot-like features that are characterized by the absence of a penumbra, carry fluxes of some 10 20 to 10 21 Mx (Thomas and Weiss 2004;Sobotka et al 2012). Magnetic elements within ARs carry fluxes of 10 18 to 10 20 Mx (Abramenko and Longcope 2005).…”

Section: Magnetic Flux Emergencementioning

confidence: 99%

“…The flux in ARs that is not in the form of sunspots is concentrated in either pores or magnetic elements. The properties of pores include diameters of some Mm and field strengths of 1 to 2 kG (Thomas and Weiss 2004;Sobotka et al 2012). Magnetic elements have diameters smaller than ≈350 km and exhibit field strengths of 1 to 2 kG (Stenflo 1973;Rabin 1992;Rüedi et al 1992).…”

Section: Temporal Evolution Of the Magnetic Fieldmentioning

confidence: 99%

The magnetic field in the solar atmosphere

Wiegelmann

Thalmann

Solanki

2014

Astron Astrophys Rev

176

125

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This publication provides an overview of magnetic fields in the solar atmosphere with the focus lying on the corona. The solar magnetic field couples the solar interior with the visible surface of the Sun and with its atmosphere. It is also responsible for all solar activity in its numerous manifestations. Thus, dynamic phenomena such as coronal mass ejections and flares are magnetically driven. In addition, the field also plays a crucial role in heating the solar chromosphere and corona as well as in accelerating the solar wind. Our main emphasis is the magnetic field in the upper solar atmosphere so that photospheric and chromospheric magnetic structures are mainly discussed where relevant for higher solar layers. Also, the discussion of the solar atmosphere and activity is limited to those topics of direct relevance to the magnetic field. After giving a brief overview about the solar magnetic field in general and its global structure, we discuss in more detail the magnetic field in active regions, the quiet Sun and coronal holes.

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