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23 results on '"Yardley, S. L."'

1. Searching for evidence of subchromospheric magnetic reconnection on the Sun

Author

Baker, D., van Driel-Gesztelyi, L., James, A. W., Demoulin, P., To, A. S. H., Murabito, M., Long, D. M., Brooks, D. H., McKevitt, J., Laming, J. M., Green, L. M., Yardley, S. L., Valori, G., Mihailescu, T., Matthews, S. A., and Kuniyoshi, H.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

Within the coronae of stars, abundances of those elements with low first ionization potential (FIP) often differ from their photospheric values. The coronae of the Sun and solar-type stars mostly show enhancements of low-FIP elements (the FIP effect) while more active stars such as M dwarfs have coronae generally characterized by the inverse-FIP (I-FIP) effect. Highly localized regions of I-FIP effect solar plasma have been observed by Hinode/EIS in a number of highly complex active regions, usually around strong light bridges of the umbrae of coalescing/merging sunspots. These observations can be interpreted in the context of the ponderomotive force fractionation model which predicts that plasma with I-FIP effect composition is created by the refraction of waves coming from below the plasma fractionation region in the chromosphere. A plausible source of these waves is thought to be reconnection in the (high-plasma \b{eta}) subchromospheric magnetic field. In this study, we use the 3D visualization technique of Chintzoglou & Zhang (2013) combined with observations of localized I-FIP effect in the corona of AR 11504 to identify potential sites of such reconnection and its possible consequences in the solar atmosphere. We found subtle signatures of episodic heating and reconnection outflows in the expected places, in between magnetic flux tubes forming a light bridge, within the photosphere of the active region. Furthermore, on either side of the light bridge, we observed small antiparallel horizontal magnetic field components supporting the possibility of reconnection occuring where we observe I-FIP plasma. When taken together with the I-FIP effect observations, these subtle signatures provide a compelling case for indirect observational evidence of reconnection below the fractionation layer of the chromosphere, however, direct evidence remains elusive., Comment: Accepted ApJ

Published
2024

2. SPICE Connection Mosaics to link the Sun's surface and the heliosphere

Author

Varesano, T., Hassler, D. M., Prado, N. Zambrana, Plowman, J., Del Zanna, G., Parenti, S., Mason, H. E., Giunta, A., Auchere, F., Carlsson, M., Fludra, A., Peter, H., Muller, D., Williams, D., Cuadrado, R. Aznar, Barczynski, K., Buchlin, E., Caldwell, M., Fredvik, T., Grundy, T., Guest, S., Harra, L., Janvier, M., Kucera, T., Leeks, S., Schmutz, W., Schuehle, U., Sidher, S., Teriaca, L., Thompson, W., and Yardley, S. L.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

We present an analysis of the first connection mosaic made by the SPICE instrument on board of the ESA / NASA Solar Orbiter mission on March 2nd, 2022. The data will be used to map coronal composition that will be compared with in-situ measurements taken by SWA/HIS to establish the coronal origin of the solar wind plasma observed at Solar Orbiter. The SPICE spectral lines were chosen to have varying sensitivity to the First Ionization Potential (FIP) effect, and therefore the radiances of the spectral lines will vary significantly depending on whether the elemental composition is coronal or photospheric. We investigate the link between the behavior of sulfur with the hypothesis that Alfv\'en waves drive FIP fractionation above the chromosphere. We perform temperature diagnostics using line ratios and Emission Measure (EM) loci, and compute relative FIP biases using three different approaches (two line ratio (2LR), ratios of linear combinations of spectral lines (LCR), and differential emission measure (DEM) inversion) to perform composition diagnostics in the corona. We then compare the SPICE composition analysis and EUI data of the potential solar wind source regions to the SWA / HIS data products. Radiance maps are extracted from SPICE spectral data cubes, with values matching previous observations. We find isothermal plasma of around LogT = 5.8 for the active region loops targeted, and that higher FIP-bias values are present at the footpoints of the coronal loops associated with two active regions. Comparing the results with the SWA/HIS data products encourages us to think that Solar Orbiter was connected to a source of slow solar wind during this observation campaign. We demonstrate FIP fractionation in observations of the upper chromosphere and transition region, emphasized by the behavior of the intermediate-FIP element sulfur., Comment: 20 pages, 19 figures, submitted to A&A on August 3rd, accepted on February 12th, 2024

Published
2023
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3. Observational Evidence of S-Web Source of the Slow Solar Wind

Author

Baker, D., Demoulin, P., Yardley, S. L., Mihailescu, T., van Driel-Gesztelyi, L., D'Amicis, R., Long, D. M., To, A. S. H., Owen, C. J., Horbury, T. S., Brooks, D. H., Perrone, D., French, R. J., James, A. W., Janvier, M., Matthews, S., Stangalini, M., Valori, G., Smith, P., Cuadrado, R. Anzar, Peter, H., Schuehle, U., Harra, L., Barczynski, K., Berghmans, D., Zhukov, A. N., Rodriguez, L., and Verbeeck, C.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

From 2022 March 18-21, active region (AR) 12967 was tracked simultaneously by Solar Orbiter (SO) at 0.35 au and Hinode/EIS at Earth. During this period, strong blue-shifted plasma upflows were observed along a thin, dark corridor of open field originating at the AR's leading polarity and continuing towards the southern extension of the northern polar coronal hole. A potential field source surface (PFSS) model shows large lateral expansion of the open magnetic field along the corridor. Squashing factor Q-maps of the large scale topology further confirm super-radial expansion in support of the S-Web theory for the slow wind. The thin corridor of upflows is identified as the source region of a slow solar wind stream characterised by approx. 300 km s-1 velocities, low proton temperatures of approx. 5 eV, extremely high density over 100 cm-3, and a short interval of moderate Alfvenicity accompanied by switchback events. When connectivity changes from the corridor to the eastern side of the AR, the in situ plasma parameters of the slow wind indicate a distinctly different source region. These observations provide strong evidence that the narrow open field corridors, forming part of the S-Web, produce extreme properties in their associated solar wind streams., Comment: Accepted ApJ

Published
2023
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4. Widespread Occurrence of High-Velocity Upflows in Solar Active Regions

Author

Yardley, S. L., Brooks, D. H., and Baker, D.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

We performed a systematic study of 12 active regions (ARs) with a broad range of areas, magnetic flux and associated solar activity in order to determine whether there are upflows present at the AR boundaries and if these upflows exist, whether there is a high speed asymmetric blue wing component present in the upflows. To identify the presence and locations of the AR upflows we derive relative Doppler velocity maps by fitting a Gaussian function to {\it Hinode}/EIS Fe XII 192.394\,\AA\ line profiles. To determine whether there is a high speed asymmetric component present in the AR upflows we fit a double Gaussian function to the Fe XII 192.394\,\AA\ mean spectrum that is computed in a region of interest situated in the AR upflows. Upflows are observed at both the east and west boundaries of all ARs in our sample with average upflow velocities ranging between -5 to -26~km s$^{-1}$. A blue wing asymmetry is present in every line profile. The intensity ratio between the minor high speed asymmetric Gaussian component compared to the main component is relatively small for the majority of regions however, in a minority of cases (8/30) the ratios are large and range between 20 to 56~\%. These results suggest that upflows and the high speed asymmetric blue wing component are a common feature of all ARs., Comment: Accepted in A&A, 5 pages, 3 figures

Published
2021
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5. Decoding the Pre-Eruptive Magnetic Field Configurations of Coronal Mass Ejections

Author

Patsourakos, S., Vourlidas, A., Török, T., Kliem, B., Antiochos, S. K., Archontis, V., Aulanier, G., Cheng, X., Chintzoglou, G., Georgoulis, M. K., Green, L. M., Leake, J. E., Moore, R., Nindos, A., Syntelis, P., Yardley, S. L., Yurchyshyn, V., and Zhang, J.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

A clear understanding of the nature of the pre-eruptive magnetic field configurations of Coronal Mass Ejections (CMEs) is required for understanding and eventually predicting solar eruptions. Only two, but seemingly disparate, magnetic configurations are considered viable; namely, sheared magnetic arcades (SMA) and magnetic flux ropes (MFR). They can form via three physical mechanisms (flux emergence, flux cancellation, helicity condensation) . Whether the CME culprit is an SMA or an MFR, however, has been strongly debated for thirty years. We formed an International Space Science Institute (ISSI) team to address and resolve this issue and report the outcome here. We review the status of the field across modeling and observations, identify the open and closed issues, compile lists of SMA and MFR observables to be tested against observations and outline research activities to close the gaps in our current understanding. We propose that the combination of multi-viewpoint multi-thermal coronal observations and multi-height vector magnetic field measurements is the optimal approach for resolving the issue conclusively. We demonstrate the approach using MHD simulations and synthetic coronal images. Our key conclusion is that the differentiation of pre-eruptive configurations in terms of SMAs and MFRs seems artificial. Both observations and modeling can be made consistent if the pre-eruptive configuration exists in a hybrid state that is continuously evolving from an SMA to an MFR. Thus, the 'dominant' nature of a given configuration will largely depend on its evolutionary stage (SMA-like early-on, MFR-like near the eruption)., Comment: Space Science Reviews, accepted for publication

Published
2020
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6. A New Space Weather Tool for Identifying Eruptive Active Regions

Author

Pagano, P., Mackay, D. H., and Yardley, S. L.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

One of the main goals of solar physics is the timely identification of eruptive active regions. Space missions such as Solar Orbiter or future Space Weather forecasting missions would largely benefit from this achievement. Our aim is to produce a relatively simple technique that can provide real time indications or predictions that an active region will produce an eruption. We expand on the theoretical work of \citet{Pagano2019fp} that was able to distinguish eruptive from non-eruptive active regions. From this we introduce a new operational metric that uses a combination of observed line-of-sight magnetograms, 3D data-driven simulations and the projection of the 3D simulations forward in time. Results show that the new metric correctly distinguishes active regions as eruptive when observable signatures of eruption have been identified and as non-eruptive when there are no observable signatures of eruption. After successfully distinguishing eruptive from non-eruptive active regions we illustrate how this metric may be used in a "real-time" operational sense were three levels of warning are categorised. These categories are: high risk (red), medium risk (amber) and low risk (green) of eruption. Through considering individual cases we find that the separation into eruptive and non-eruptive active regions is more robust the longer the time series of observed magnetograms used to simulate the build up of magnetic stress and free magnetic energy within the active region. Finally, we conclude that this proof of concept study delivers promising results where the ability to categorise the risk of an eruption is a major achievement.

Published
2019
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7. A Prospective New Diagnostic Technique for Distinguishing Eruptive and Non-Eruptive Active Regions

Author

Pagano, P., Mackay, D. H., and Yardley, S. L.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

Active regions are the source of the majority of magnetic flux rope ejections that become Coronal Mass Ejections (CMEs). To identify in advance which active regions will produce an ejection is key for both space weather prediction tools and future science missions such as Solar Orbiter. The aim of this study is to develop a new technique to identify which active regions are more likely to generate magnetic flux rope ejections. The new technique will aim to: (i) produce timely space weather warnings and (ii) open the way to a qualified selection of observational targets for space-borne instruments. We use a data-driven Non-linear Force-Free Field (NLFFF) model to describe the 3D evolution of the magnetic field of a set of active regions. We determine a metric to distinguish eruptive from non-eruptive active regions based on the Lorentz force. Furthermore, using a subset of the observed magnetograms, we run a series of simulations to test whether the time evolution of the metric can be predicted. The identified metric successfully differentiates active regions observed to produce eruptions from the non-eruptive ones in our data sample. A meaningful prediction of the metric can be made between 6 to 16 hours in advance. This initial study presents an interesting first step in the prediction of CME onset using only LOS magnetogram observations combined with NLFFF modelling. Future studies will address how to generalise the model such that it can be used in a more operational sense and for a variety of simulation approaches.

Published
2019
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8. The role of flux cancellation in eruptions from bipolar active regions

Author

Yardley, S. L., Green, L. M., Van Driel-Gesztelyi, L., Williams, D. R., and Mackay, D. H.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

The physical processes or trigger mechanisms that lead to the eruption of coronal mass ejections (CMEs), the largest eruptive phenomenon in the heliosphere, are still undetermined. Low-altitude magnetic reconnection associated with flux cancellation appears to play an important role in CME occurrence as it can form an eruptive configuration and reduce the magnetic flux that contributes to the overlying, stabilising field. We conduct the first comprehensive study of 20 small bipolar active regions in order to probe the role of flux cancellation as an eruption trigger mechanism. We categorise eruptions from the bipolar regions into three types related to location and find that the type of eruption produced depends on the evolutionary stage of the active region. In addition we find that active regions that form eruptive structures by flux cancellation (low-altitude reconnection) had, on average, lower flux cancellation rates than the active region sample as a whole. Therefore, while flux cancellation plays a key role, by itself it is insufficient for the production of an eruption. The results support that although flux cancellation in a sheared arcade may be able to build an eruptive configuration, a successful eruption depends upon the removal of sufficient overlying and stabilising field. Convergence of the bipole polarities also appears to be present in regions that produce an eruption. These findings have important implications for understanding the physical processes that occur on our Sun in relation to CMEs and for space weather forecasting., Comment: 16 pages, 4 figures

Published
2018
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9. The role of flux cancellation in the formation of filaments and eruptive structures

Author

Yardley, S. L., Green, L. M., Williams, D. R., and van Driel-Gesztelyi, L.

Subjects
500
Abstract

The work conducted in this thesis represents a contribution towards understanding the important processes involved in the formation of filaments and eruptive structures in the solar atmosphere. In particular, the role that ongoing photospheric flux cancellation and associated magnetic reconnection plays in the origin of filament plasma. Also, to study how the magnetic field configuration evolves as flux cancellation proceeds to find indications of the onset of filament eruptions as coronal mass ejections (CMEs). This process is capable of re-configuring the supporting magnetic field from a sheared coronal arcade to a flux rope configuration, building up non-potential field in the atmosphere and storing free magnetic energy along the polarity inversion line. These helical configurations consist of concave-up sections or magnetic dips that provide locations for filament material to be supported against gravity. Flux cancellation observations, whereby small-scale opposite polarity features converge, collide and subsequently dis- appear in line-of-sight magnetic field can therefore, provide a way to investigate how much magnetic flux has been built into the magnetic field configuration that contains the filament before eruption. This process is crucial to the understanding of the onset of CMEs. In this thesis, a small sub-set of active regions have been studied. Observations of the photospheric field have been used to study the field evolution of active regions and its relationship to eruptions. To study the magnetic evolution of these regions an automated algorithm has been developed which tracks magnetic features in line-of-sight magnetic field data to calculate the total quantity and rate of flux cancellation. Chromospheric and coronal plasma observations have been used to study the presence of filament material and plasma flows, in relation to flux cancellation sites. Finally, these observations have been compared to the field configuration and locations of magnetic dips present in non-linear force-free field models.

Published
2017

10. Flux cancellation and the evolution of the eruptive filament of 2011 June 7

Author

Yardley, S. L., Green, L. M., Williams, D. R., van Driel-Gesztelyi, L., Valori, G., and Dacie, S.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

We investigate whether flux cancellation is responsible for the formation of a very massive filament resulting in the spectacular 2011 June 7 eruption. We analyse and quantify the amount of flux cancellation that occurs in NOAA AR 11226 and its two neighbouring ARs (11227 & 11233) using line-of-sight magnetograms from the Heliospheric Magnetic Imager. During a 3.6-day period building up to the filament eruption, 1.7 x 10^21 Mx, 21% of AR 11226's maximum magnetic flux, was cancelled along the polarity inversion line (PIL) where the filament formed. If the flux cancellation continued at the same rate up until the eruption then up to 2.8 x 10^21 Mx (34% of the AR flux) may have been built into the magnetic configuration that contains the filament plasma. The large flux cancellation rate is due to an unusual motion of the positive polarity sunspot, which splits, with the largest section moving rapidly towards the PIL. This motion compresses the negative polarity and leads to the formation of an orphan penumbra where one end of the filament is rooted. Dense plasma threads above the orphan penumbra build into the filament, extending its length, and presumably injecting material into it. We conclude that the exceptionally strong flux cancellation in AR 11226 played a significant role in the formation of its unusually massive filament. In addition, the presence and coherent evolution of bald patches in the vector magnetic field along the PIL suggests that the magnetic field configuration supporting the filament material is that of a flux rope., Comment: 18 pages, 7 figures. Submitted to ApJ in December 2015, accepted in June 2016

Published
2016
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11. FIP Bias Evolution in a Decaying Active Region

Author

Baker, D., Brooks, D. H., Démoulin, P., Yardley, S. L., van Driel-Gesztelyi, L., Long, D. M., and Green, L. M.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

Solar coronal plasma composition is typically characterized by first ionization potential (FIP) bias. Using spectra obtained by Hinode's EUV Imaging Spectrometer (EIS) instrument, we present a series of large-scale, spatially resolved composition maps of active region (AR) 11389. The composition maps show how FIP bias evolves within the decaying AR from 2012 January 4-6. Globally, FIP bias decreases throughout the AR. We analyzed areas of significant plasma composition changes within the decaying AR and found that small-scale evolution in the photospheric magnetic field is closely linked to the FIP bias evolution observed in the corona. During the AR's decay phase, small bipoles emerging within supergranular cells reconnect with the pre-existing AR field, creating a pathway along which photospheric and coronal plasmas can mix. The mixing time scales are shorter than those of plasma enrichment processes. Eruptive activity also results in shifting the FIP bias closer to photospheric in the affected areas. Finally, the FIP bias still remains dominantly coronal only in a part of the AR's high-flux density core. We conclude that in the decay phase of an AR's lifetime, the FIP bias is becoming increasingly modulated by episodes of small-scale flux emergence, i.e. decreasing the AR's overall FIP bias. Our results show that magnetic field evolution plays an important role in compositional changes during AR development, revealing a more complex relationship than expected from previous well-known Skylab results showing that FIP bias increases almost linearly with age in young ARs (Widing $\&$ Feldman, 2001, ApJ, 555, 426).

Published
2015
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13. Observational Evidence of S-web Source of the Slow Solar Wind

Author

Baker, D., primary, Démoulin, P., additional, Yardley, S. L., additional, Mihailescu, T., additional, van Driel-Gesztelyi, L., additional, D’Amicis, R., additional, Long, D. M., additional, To, A. S. H., additional, Owen, C. J., additional, Horbury, T. S., additional, Brooks, D. H., additional, Perrone, D., additional, French, R. J., additional, James, A. W., additional, Janvier, M., additional, Matthews, S., additional, Stangalini, M., additional, Valori, G., additional, Smith, P., additional, Cuadrado, R. Aznar, additional, Peter, H., additional, Schuehle, U., additional, Harra, L., additional, Barczynski, K., additional, Berghmans, D., additional, Zhukov, A. N., additional, Rodriguez, L., additional, and Verbeeck, C., additional

Published
2023
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14. Application of historic datasets to understanding open solar flux and the 20th-century grand solar maximum:2. Solar observations

Author

Lockwood, M. (Mike), Owens, M. J. (Mathew J.), Yardley, S. L. (Stephanie L.), Virtanen, I. O. (Iiro O. I.), Yeates, A. R. (Anthony R.), Muñoz-Jaramillo, A. (Andrés), Lockwood, M. (Mike), Owens, M. J. (Mathew J.), Yardley, S. L. (Stephanie L.), Virtanen, I. O. (Iiro O. I.), Yeates, A. R. (Anthony R.), and Muñoz-Jaramillo, A. (Andrés)

Abstract

We study historic observations of solar activity from the 20th-century rise towards the peak of the Modern Grand Solar Maximum (MGSM) and compare with observations of the decline that has occurred since. The major difference in available solar observations of the rise and of the fall are accurate magnetograms from solar magnetographs: we here use synthetic magnetograms to interpret the rise and employ historic observations of Polar Crown Filaments to test them and verify their use. We show that eclipse images at sunspot minimum reveal the long-term variation of open flux deduced from geomagnetic observations in Paper 1 (Lockwood et al., 2022). We also make use of polar coronal hole fluxes derived from historic white light images of polar faculae, but have to consider the implications of the fact that these facular images do not tell us the polarity of the field. Given this caveat, the agreement between the polar coronal hole fluxes and the values derived from open flux continuity modelling based on sunspot numbers is extremely good. This comparison indicates that one possible solution to the “open flux problem” is open flux within the streamer belt that potential-based modelling of coronal fields from photospheric fields is not capturing. We take a detailed look at the solar cycle at the peak of the MGSM, cycle 19, and show the variation of the polar coronal hole fluxes and the inferred poleward flux surges are predictable from the asymmetries in flux emergence in the two hemispheres with implied transequatorial flux transfer and/or “anti-Hale” (or more general “rogue” active region flux) emergence late in the sunspot cycle.

Published
2022

15. Evolution of Plasma Composition in an Eruptive Flux Rope

Author

Baker, D., primary, Green, L. M., additional, Brooks, D. H., additional, Démoulin, P., additional, van Driel-Gesztelyi, L., additional, Mihailescu, T., additional, To, A. S. H., additional, Long, D. M., additional, Yardley, S. L., additional, Janvier, M., additional, and Valori, G., additional

Published
2022
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18. Decoding the Pre-Eruptive Magnetic Field Configurations of Coronal Mass Ejections

Author

Patsourakos, S., primary, Vourlidas, A., additional, Török, T., additional, Kliem, B., additional, Antiochos, S. K., additional, Archontis, V., additional, Aulanier, G., additional, Cheng, X., additional, Chintzoglou, G., additional, Georgoulis, M. K., additional, Green, L. M., additional, Leake, J. E., additional, Moore, R., additional, Nindos, A., additional, Syntelis, P., additional, Yardley, S. L., additional, Yurchyshyn, V., additional, and Zhang, J., additional

Published
2020
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