Oscillations above sunspots from the temperature minimum to the corona

Кобанов, Н. И.; Chelpanov, Andrei; Kolobov, D. Yu.

doi:10.1051/0004-6361/201220548

Cited by 27 publications

(20 citation statements)

References 33 publications

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“…For the purposes of that work, no filtering was performed in the spatial domain. However, examining time-lapse movies of the temporally filtered Hα images reveals a plethora of dynamic wave activity across a variety of spatial scales, particularly within the umbra where a dominant periodicity of ∼180 s was uncovered, which is consistent with the work of Kobanov et al (2011Kobanov et al ( , 2013Kobanov et al ( , 2015. The enhanced oscillations, which are clearly observed in the temporally (150 -180 s) filtered Hα observations, are similar in magnitude to the outputs of chromospheric umbral resonance models put forward by Zhugzhda & Locans (1981) and Staude et al (1985), whereby the upwardly propagating slow magneto-acoustic waves, which do not violate the acoustic cut-off period (e.g., Bel & Leroy 1977;Fleck & Schmitz 1991;Zhugzhda 2008;Yuan et al 2014b;Snow et al 2015, to name but a few), are reflected continuously between the steep temperature gradients present close to the photospheric temperature minimum and at the transition region boundary.…”

Section: Analysis and Discussionsupporting

confidence: 87%

An Inside Look at Sunspot Oscillations with Higher Azimuthal Wavenumbers

Jess

Doorsselaere

Verth

et al. 2017

ApJ

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Solar chromospheric observations of sunspot umbrae offer an exceptional view of magnetohydrodynamic wave phenomena. In recent years, a wealth of wave signatures related to propagating magneto-acoustic modes have been presented, which demonstrate complex spatial and temporal structuring of the wave components. Theoretical modelling has demonstrated how these ubiquitous waves are consistent with an m = 0 slow magneto-acoustic mode, which are excited by trapped sub-photospheric acoustic (p-mode) waves. However, the spectrum of umbral waves is broad, suggesting that the observed signatures represent the superposition of numerous frequencies and/or modes. We apply Fourier filtering, in both spatial and temporal domains, to extract chromospheric umbral wave characteristics consistent with an m = 1 slow magneto-acoustic mode. This identification has not been described before. Angular frequencies of 0.037 ± 0.007 rad/s (2.1 ± 0.4 deg/s, corresponding to a period ≈170 s) for the m = 1 mode are uncovered for spatial wavenumbers in the range of 0.45 < k < 0.90 arcsec −1 (5000 − 9000 km). Theoretical dispersion relations are solved, with corresponding eigenfunctions computed, which allows the density perturbations to be investigated and compared with our observations. Such magnetohydrodynamic modelling confirms our interpretation that the identified wave signatures are the first direct observations of an m = 1 slow magneto-acoustic mode in the chromospheric umbra of a sunspot.

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Section: Analysis and Discussionsupporting

confidence: 87%

An Inside Look at Sunspot Oscillations with Higher Azimuthal Wavenumbers

Jess

Doorsselaere

Verth

et al. 2017

ApJ

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“…Based on the intrinsic relationships they find between the underlying magnetic field geometries connecting the photosphere to the chromosphere, and the characteristics of running penumbral waves observed in the upper chromosphere, and Jess et al (2013) conclude that running penumbral wave phenomena are the chromospheric signature of upwardly propagating magneto-acoustic waves generated in the photosphere. Kobanov et al (2013a) obtained similar results for the wave power distribution at different frequencies and heights. In addition, the latter authors measured the time lag between oscillations at different levels.…”

Section: Chromospheric Running Penumbral Wavessupporting

confidence: 61%

“…This argument has been used to suggest that running penumbral waves are not associated with similar waves in the umbra and that very likely umbral and penumbral oscillations initially propagate along different magnetic field lines. Through careful consideration of the magnetic vector, Bloomfield et al (2007a) provided evidence that velocity signatures of running penumbral waves observed in the He i 10830 multiplet are more compatible with upwardpropagating waves than with trans-sunspot waves, see Section 8. , , Jess et al (2013), and Kobanov et al (2013a) have investigated the role of the magnetic field topology in the propagation characteristics of umbral and running penumbral waves at chromospheric, transition region and coronal layers. They find an increase of the oscillatory period of brightness oscillations as a function of distance from the umbral center.…”

Section: Chromospheric Running Penumbral Wavesmentioning

confidence: 99%

Oscillations and Waves in Sunspots

Khomenko

Collados

2015

Living Rev. Sol. Phys.

149

118

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A magnetic field modifies the properties of waves in a complex way. Significant advances have been made recently in our understanding of the physics of sunspot waves with the help of high-resolution observations, analytical theories, as well as numerical simulations. We review the current ideas in the field, providing the most coherent picture of sunspot oscillations as by present understanding. Article RevisionsLiving Reviews supports two ways of keeping its articles up-to-date:Fast-track revision. A fast-track revision provides the author with the opportunity to add short notices of current research results, trends and developments, or important publications to the article. A fast-track revision is refereed by the responsible subject editor. If an article has undergone a fast-track revision, a summary of changes will be listed here.Major update. A major update will include substantial changes and additions and is subject to full external refereeing. It is published with a new publication number.For detailed documentation of an article's evolution, please refer to the history document of the article's online version at http://dx

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“…High spatial and temporal resolution observations provided a chance to reveal spatial distributions of sunspot oscillations in different atmospheric layers. Using data observed by Sayan Solar Observatory and Solar Dynamics Observatory/Atmospheric Imaging Assembly (SDO/AIA; Lemen et al 2012;Pesnell et al 2012), Kobanov et al (2013) found that the powers of the three-minute oscillation mainly concentrate within an umbra in the temperature minimum and chromosphere. Although the oscillation expands significantly in the transition region and lower corona, it is still limited within the umbra.…”

Section: Introductionmentioning

confidence: 99%

Spatial distributions of sunspot oscillation modes at different temperatures

Wang

Feng

Deng

et al. 2020

Res. Astron. Astrophys.

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Three-and five-minute oscillations of sunspots have different spatial distributions in the solar atmospheric layers. The spatial distributions are crucial to reveal the physical origin of sunspot oscillations and to investigate their propagation. In this study, six sunspots observed by Solar Dynamics Observatory/Atmospheric Imaging Assembly were used to obtain the spatial distributions of three-and five-minute oscillations. The fast Fourier transform method is applied to represent the power spectra of oscillation modes. We find that, from the temperature minimum to the lower corona, the powers of the five-minute oscillation exhibit a circle-shape distribution around its umbra, and the shapes gradually expand with temperature increase. However, the circle-shape is disappeared and the powers of the oscillations appear to be very disordered in the higher corona. This indicates that the five-minute oscillation can be suppressed in the high-temperature region. For the three-minute oscillations, from the temperature minimum to the high corona, their powers mostly distribute within an umbra, and part of them locate at the coronal fan loop structures. Moreover, those relative higher powers are mostly concentrated in the position of coronal loop footpoints.

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Oscillations above sunspots from the temperature minimum to the corona

Cited by 27 publications

References 33 publications

An Inside Look at Sunspot Oscillations with Higher Azimuthal Wavenumbers

An Inside Look at Sunspot Oscillations with Higher Azimuthal Wavenumbers

Oscillations and Waves in Sunspots

Spatial distributions of sunspot oscillation modes at different temperatures

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