Statistical Analysis and Catalog of Non-polar Coronal Holes Covering the SDO-Era Using CATCH

Heinemann, Stephan G.; Temmer, Manuela; Heinemann, Niko; Dissauer, Karin; Samara, Evangelia; Jerčić, Veronika; Hofmeister, Stefan J.; Veronig, Astrid

doi:10.1007/s11207-019-1539-y

Cited by 58 publications

(82 citation statements)

References 64 publications

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“…The total area covered by long-lived magnetic elements with lifetimes > 4 days is strongly correlated with the unbalanced magnetic flux of CHs (cc = 0.99). These magnetic elements account for ≈ 68% of the unbalanced "open" magnetic flux of CHs at typical coverages of about 3% of the total CH area (Hofmeister et al, 2019;Heinemann et al, 2019). Heinemann et al (2018a,b) investigated a long-lived low-latitude CH observed by the Solar Dynamics Observatory (SDO) and Solar Terrestrial Relations Observatory (STEREO) spacecraft over ten solar rotations from February 2012 to October 2012 (see Figure 7).…”

Section: Introductionmentioning

confidence: 99%

Differential Emission Measure Plasma Diagnostics of a Long-Lived Coronal Hole

et al. 2020

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We use Solar Dynamics Observatory (SDO)/Atmospheric Imaging Assembly (AIA) data to reconstruct the plasma properties from differential emission measure (DEM) analysis for a previously studied long-lived, low-latitude coronal hole (CH) over its lifetime of ten solar rotations. We initially obtain a non-isothermal DEM distribution with a dominant component centered around 0.9 MK and a secondary smaller component at 1.5-2.0 MK. We find that deconvolving the data with the instrument point spread function (PSF) to account for long-range scattered light reduces the secondary hot component. Using the 2012 Venus transit and a 2013 lunar eclipse to test the efficiency of this deconvolution, significant amounts of residual stray light are found for the occulted areas. Accounting for this stray light in the error budget of the different AIA filters further reduces the secondary hot emission, yielding CH DEM distributions that are close to isothermal with the main contribution centered around 0.9 MK. Based on these DEMs, we analyze the evolution of the emission measure (EM), density, and averaged temperature during the CH's lifetime. We find that once the CH is clearly observed in EUV images, the bulk of the CH plasma reveals a quite constant state, i.e. temperature and density reveal no major changes, whereas the total CH area and the photospheric magnetic fine structure inside the CH show a distinct evolutionary pattern. These findings suggest that CH plasma properties are mostly "set" at the CH formation or/and that all CHs have similar plasma properties.

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Section: Introductionmentioning

confidence: 99%

Differential Emission Measure Plasma Diagnostics of a Long-Lived Coronal Hole

et al. 2020

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“…Any instrument (in this case AIA) suffers inevitable depletions (e.g., decreasing sensitivity, aging filters, and others), distortion of optical system, and scattered light to name just a few. But in the context of this study, especially regarding the CH detection, we do not believe that these uncertainties introduce significant errors, as each CH was manually tuned to account for such instrumental and observational changes (see for more details Heinemann et al, ). For the case of large CHs we have only one point so the relation between coverage and area remains inconclusive.…”

Section: Resultsmentioning

confidence: 99%

“…The CH boundaries were extracted using catch (Heinemann et al, 2019), an intensity threshold algorithm that is modulated by the intensity gradient along the CHs boundary. The SSW-IDL-written GUI enables the user to optimize the threshold used for the CH extraction by considering the average intensity profile at the Journal of Geophysical Research: Space Physics 10.1029/2019JA027173 boundary to find the highest gradient.…”

Section: Extracting Ch Boundaries With Catchmentioning

confidence: 99%

“…The lower and upper bounds present a significantly overestimated and underestimated threshold for the extraction. For further information on the algorithm, we refer to Heinemann et al (2019). Line-of-sight effects can introduce errors in the boundary extraction of the CH with CATCH; however, these errors are of the order of 2 to 8 arcseconds.…”

Section: Extracting Ch Boundaries With Catchmentioning

confidence: 99%

“…To do that, we selected a sample of 15 CHs located around the central meridian of the solar disk as viewed from Earth, but at different latitudes (see section ). Using CATCH (Collection of Analysis Tools for Coronal Holes; Heinemann et al, ), we extracted the boundaries of these CHs based on their appearance in EUV filtergrams at 193 Å (section ). We reconstructed their areas with EUHFORIA, by varying the paired values for the heights of the source surface and the inner boundary of the SCS model, in order to find optimal values that produce a better match between modeled and observed CH areas (section ).…”

Section: Introductionmentioning

confidence: 99%

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Reconstructing Coronal Hole Areas With EUHFORIA and Adapted WSA Model: Optimizing the Model Parameters

et al. 2019

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The adopted Wang-Sheeley-Arge (WSA) model embedded in EUHFORIA (EUropean Heliospheric FORecasting Information Asset) is compared to EUV observations. According to the standard paradigm, coronal holes are sources of open flux; thus, we use remote sensing EUV observations and catch (Collection of Analysis Tools for Coronal Holes) to extract CH areas and compare them to the open flux areas modeled by EUHFORIA. From the adopted WSA model we employ only the Potential Field Source Surface (PFSS) model for the inner corona and the Schatten Current Sheet (SCS) model for the outer (PFSS+SCS). The height, R ss , of the outer boundary of the PFSS, known as the source surface, and the height, R i , of the inner boundary of the SCS are important parameters affecting the modeled CH areas.We investigate the impact the two model parameters can have in the modeled results. We vary R ss within the interval [1.4, 3.2]R ⊙ with a step of 0.1R ⊙ , and R i within the interval [1.3, 2.8]R ⊙ with the same step, and the condition that R i < R ss . This way we have a set of 184 initial parameters to the model, and we assess the model results for all these possible height pairs. We conclude that the default heights used so far fail in modeling accurately CH areas and lower heights need to be considered.

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