The Effects of Transients on Photospheric and Chromospheric Power Distributions

Samanta, Tanmoy; Henriques, V. M. J.; Banerjee, D.; Prasad, S. Krishna; Mathioudakis, M.; Jess, D. B.; Pant, Vaibhav

doi:10.3847/0004-637x/828/1/23

Cited by 6 publications

(6 citation statements)

References 72 publications

(115 reference statements)

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“…using a double Voigt model), then the resulting Doppler velocities inferred from the emission Voigt fit are shown in the right panel of figure 7. In particular, it can be seen in the right panel of figure 7 that many of the derived Doppler velocities associated with dynamic phenomena appear to rapidly change between neighbouring pixels, an effect that has been documented in previous velocity studies of the solar chromosphere [58][59][60]. These rapid velocity excursions appear to be closely linked to instances when the Ca II 8542 Å line goes into emission.…”

Section: Proof Of Concept Testing With Ibis Datasupporting

confidence: 61%

Accurately constraining velocity information from spectral imaging observations using machine learning techniques

MacBride

Jess

Grant

et al. 2020

Phil. Trans. R. Soc. A.

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Determining accurate plasma Doppler (line-of-sight) velocities from spectroscopic measurements is a challenging endeavour, especially when weak chromospheric absorption lines are often rapidly evolving and, hence, contain multiple spectral components in their constituent line profiles. Here, we present a novel method that employs machine learning techniques to identify the underlying components present within observed spectral lines, before subsequently constraining the constituent profiles through single or multiple Voigt fits. Our method allows active and quiescent components present in spectra to be identified and isolated for subsequent study. Lastly, we employ a Ca ɪɪ 8542 Å spectral imaging dataset as a proof-of-concept study to benchmark the suitability of our code for extracting two-component atmospheric profiles that are commonly present in sunspot chromospheres. Minimization tests are employed to validate the reliability of the results, achieving median reduced χ 2 -values equal to 1.03 between the observed and synthesized umbral line profiles. This article is part of the Theo Murphy meeting issue ‘High-resolution wave dynamics in the lower solar atmosphere’.

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Section: Proof Of Concept Testing With Ibis Datasupporting

confidence: 61%

Accurately constraining velocity information from spectral imaging observations using machine learning techniques

MacBride

Jess

Grant

et al. 2020

Phil. Trans. R. Soc. A.

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“…The pronounced 3-min fluctuations have often been observed in the line-of-sight velocity and/or intensity signals, in both quiet and active regions, through chromospheric spectral lines such as Ca II H & K [27][28][29][30], Ca II infrared triplet [30][31][32][33], Hα [34], He I 1083 nm [28,35,36] and Mg II h & k [37]. In the quiet Sun, while the 3-min oscillations have been shown in many observations of the low-to-mid chromosphere (or using relatively broad-band filters), a lack of such fluctuations in intensity image sequences of Hα line-core observations have also been reported [38]. Samanta et al [38] showed, however, that the dominating 3-min oscillations could be detected in the line-of-sight velocities of their Hα observations (i.e.…”

Section: Introductionmentioning

confidence: 99%

“…In the quiet Sun, while the 3-min oscillations have been shown in many observations of the low-to-mid chromosphere (or using relatively broad-band filters), a lack of such fluctuations in intensity image sequences of H α line-core observations have also been reported [38]. Samanta et al [38] showed, however, that the dominating 3-min oscillations could be detected in the line-of-sight velocities of their H α observations (i.e. also at the same spectral line position; the H α line-core), but not in the intensity.…”

Section: Introductionmentioning

confidence: 99%

An overall view of temperature oscillations in the solar chromosphere with ALMA

Jafarzadeh

Wedemeyer

Fleck

et al. 2020

Phil. Trans. R. Soc. A.

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By direct measurements of the gas temperature, the Atacama Large Millimeter/submillimeter Array (ALMA) has yielded a new diagnostic tool to study the solar chromosphere. Here, we present an overview of the brightness-temperature fluctuations from several high-quality and high-temporal-resolution (i.e. 1 and 2 s cadence) time series of images obtained during the first 2 years of solar observations with ALMA, in Band 3 and Band 6, centred at around 3 mm (100 GHz) and 1.25 mm (239 GHz), respectively. The various datasets represent solar regions with different levels of magnetic flux. We perform fast Fourier and Lomb–Scargle transforms to measure both the spatial structuring of dominant frequencies and the average global frequency distributions of the oscillations (i.e. averaged over the entire field of view). We find that the observed frequencies significantly vary from one dataset to another, which is discussed in terms of the solar regions captured by the observations (i.e. linked to their underlying magnetic topology). While the presence of enhanced power within the frequency range 3–5 mHz is found for the most magnetically quiescent datasets, lower frequencies dominate when there is significant influence from strong underlying magnetic field concentrations (present inside and/or in the immediate vicinity of the observed field of view). We discuss here a number of reasons which could possibly contribute to the power suppression at around 5.5 mHz in the ALMA observations. However, it remains unclear how other chromospheric diagnostics (with an exception of H α line-core intensity) are unaffected by similar effects, i.e. they show very pronounced 3-min oscillations dominating the dynamics of the chromosphere, whereas only a very small fraction of all the pixels in the 10 ALMA datasets analysed here show peak power near 5.5 mHz. This article is part of the Theo Murphy meeting issue ‘High-resolution wave dynamics in the lower solar atmosphere’.

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“…In the quiet Sun, while the 3-min oscillations have been shown in many observations of the low-to-mid chromosphere (or using relatively broad-band filters), a lack of such fluctuations in intensity image sequences of Hα line-core observations have also been reported [38]. Samanta et al [38] showed, however, that the dominating 3-min oscillations could be detected in the line-of-sight velocities of their Hα observations (i.e., also at the same spectral line position; the Hα line-core), but not in the intensity. In the latter, they found the dominant periods (in the entire field-of-view) to be longer than five minutes.…”

Section: Introductionmentioning

confidence: 91%

“…The pronounced 3-min fluctuations have often been observed in the line-of-sight velocity and/or intensity signals, in both quiet and active regions, through chromospheric spectral lines such as Ca II H & K [27][28][29][30], Ca II infrared triplet [30][31][32][33], Hα [34], He I 1083 nm [28,35,36], and Mg II h & k [37]. In the quiet Sun, while the 3-min oscillations have been shown in many observations of the low-to-mid chromosphere (or using relatively broad-band filters), a lack of such fluctuations in intensity image sequences of Hα line-core observations have also been reported [38]. Samanta et al [38] showed, however, that the dominating 3-min oscillations could be detected in the line-of-sight velocities of their Hα observations (i.e., also at the same spectral line position; the Hα line-core), but not in the intensity.…”

Section: Introductionmentioning

confidence: 99%

An overall view of temperature oscillations in the solar chromosphere with ALMA

Jafarzadeh,

Wedemeyer,

Fleck

et al. 2020

Preprint

View full text Add to dashboard Cite

By direct measurements of the gas temperature, the Atacama Large Millimeter/sub-millimeter Array (ALMA) has yielded a new diagnostic tool to study the solar chromosphere. Here we present an overview of the brightness-temperature fluctuations from several high-quality and high-temporal-resolution (i.e., 1 and 2 sec cadence) time series of images obtained during the first two years of solar observations with ALMA, in Band 3 and Band 6, centred at around 3 mm (100 GHz) and 1.25 mm (239 GHz), respectively. The various datasets represent solar regions with different levels of magnetic flux. We perform Fast Fourier and Lomb-Scargle transforms to measure both the spatial structuring of dominant frequencies and the average global frequency distributions of the oscillations (i.e., averaged over the entire field of view). We find that the observed frequencies significantly vary from one dataset to another, which is discussed in terms of the solar regions captured by the observations (i.e., linked to their underlying magnetic topology). While the presence of enhanced power within the frequency range 3 − 5 mHz is found for the most magnetically quiescent datasets, lower frequencies dominate when there is significant influence from strong underlying magnetic field concentrations (present inside and/or in the immediate vicinity of the observed field of view). We discuss here a number of reasons which could possibly contribute to the power suppression at around 5.5 mHz in the ALMA observations. However, it remains unclear how other chromospheric diagnostics (with an exception of Hα line-core intensity) are unaffected by similar effects, i.e., they show very pronounced 3-min oscillations dominating the dynamics of the chromosphere, whereas only a very small fraction of all the pixels in the ten ALMA data sets analysed here show peak power near 5.5 mHz.

show abstract

The Effects of Transients on Photospheric and Chromospheric Power Distributions

Cited by 6 publications

References 72 publications

Accurately constraining velocity information from spectral imaging observations using machine learning techniques

Accurately constraining velocity information from spectral imaging observations using machine learning techniques

An overall view of temperature oscillations in the solar chromosphere with ALMA

An overall view of temperature oscillations in the solar chromosphere with ALMA

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