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124 results on '"Green, Lucie M."'

1. How does the critical torus instability height vary with the solar cycle?

Author

James, Alexander W., Green, Lucie M., Barnes, Graham, van Driel-Gesztelyi, Lidia, and Williams, David R.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

The ideal magnetohydrodynamic torus instability can drive the eruption of coronal mass ejections. The critical threshold of magnetic field strength decay for the onset of the torus instability occurs at different heights in different solar active regions, and understanding this variation could therefore improve space weather prediction. In this work, we aim to find out how the critical torus instability height evolves throughout the solar activity cycle. We study a significant subset of HMI and MDI Space-Weather HMI Active Region Patches (SHARPs and SMARPs) from 1996-2023, totalling 21584 magnetograms from 4436 unique active region patches. For each magnetogram, we compute the critical height averaged across the main polarity inversion line, the total unsigned magnetic flux and the separation between the positive and negative magnetic polarities. We find the critical height in active regions varies with the solar cycle, with higher (lower) average critical heights observed around solar maximum (minimum). We conclude this is because the critical height is proportional to the separation between opposite magnetic polarities, which in turn is proportional to the total magnetic flux in a region, and more magnetic regions with larger fluxes and larger sizes are observed at solar maximum. This result is noteworthy because, despite the higher critical heights, more CMEs are observed around solar maximum than at solar minimum., Comment: Accepted to ApJ. 14 pages, 6 Figures, 1 Table

Published
2024

2. Flux rope modeling of the 2022 Sep 5 CME observed by Parker Solar Probe and Solar Orbiter from 0.07 to 0.69 au

Author

Davies, Emma E., Rüdisser, Hannah T., Amerstorfer, Ute V., Möstl, Christian, Bauer, Maike, Weiler, Eva, Amerstorfer, Tanja, Majumdar, Satabdwa, Hess, Phillip, Weiss, Andreas J., Reiss, Martin A., Green, Lucie M., Long, David M., Nieves-Chinchilla, Teresa, Trotta, Domenico, Horbury, Timothy S., O'Brien, Helen, Fauchon-Jones, Edward, Morris, Jean, Owen, Christopher J., Bale, Stuart D., and Kasper, Justin C.

Subjects
Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics
Abstract

As both Parker Solar Probe (PSP) and Solar Orbiter (SolO) reach heliocentric distances closer to the Sun, they present an exciting opportunity to study the structure of CMEs in the inner heliosphere. We present an analysis of the global flux rope structure of the 2022 September 5 CME event that impacted PSP at a heliocentric distance of only 0.07 au and SolO at 0.69 au. We compare in situ measurements at PSP and SolO to determine global and local expansion measures, finding a good agreement between magnetic field relationships with heliocentric distance, but significant differences with respect to flux rope size. We use PSP/WISPR images as input to the ELEvoHI model, providing a direct link between remote and in situ observations; we find a large discrepancy between the resulting modeled arrival times, suggesting that the underlying model assumptions may not be suitable when using data obtained close to the Sun, where the drag regime is markedly different in comparison to larger heliocentric distances. Finally, we fit the SolO/MAG and PSP/FIELDS data independently with the 3DCORE model and find that many parameters are consistent between spacecraft, however, challenges are apparent when reconstructing a global 3D structure that aligns with arrival times at PSP and Solar Orbiter, likely due to the large radial and longitudinal separations between spacecraft. From our model results, it is clear the solar wind background speed and drag regime strongly affect the modeled expansion and propagation of CMEs and need to be taken into consideration.

Published
2024

3. Intriguing Plasma Composition Pattern in a Solar Active Region: a Result of Non-Resonant Alfv\'en Waves?

Author

Mihailescu, Teodora, Brooks, David H., Laming, J. Martin, Baker, Deborah, Green, Lucie M., James, Alexander W., Long, David M., van Driel-Gesztelyi, Lidia, and Stangalini, Marco

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

The plasma composition of the solar corona is different from that of the solar photosphere. Elements that have a low first ionisation potential (FIP) are preferentially transported to the corona and, therefore, show enhanced abundances in the corona compared to the photosphere. The level of enhancement is measured using the FIP bias parameter. In this work, we use data from the EUV Imaging Spectrometer (EIS) on Hinode to study the plasma composition in an active region following an episode of significant new flux emergence into the pre-existing magnetic environment of the active region. We use two FIP bias diagnostics: Si X 258.375 A/S X 264.233 A (temperature of approximately 1.5 MK) and Ca XIV 193.874 A/Ar XIV 194.396 A (temperature of approximately 4 MK). We observe slightly higher FIP bias values with the Ca/Ar diagnostic than Si/S in the newly emerging loops, and this pattern is much stronger in the preexisting loops (those that had been formed before the flux emergence). This result can be interpreted in the context of the ponderomotive force model, which proposes that the plasma fractionation is generally driven by Alfv\'en waves. Model simulations predict this difference between diagnostics using simple assumptions about the wave properties, particularly that the fractionation is driven by resonant/non-resonant waves in the emerging/preexisting loops. We propose that this results in the different fractionation patterns observed in these two sets of loops., Comment: Accepted for publication in The Astrophysical Journal

Published
2023

4. The eruption of a magnetic flux rope observed by \textit{Solar Orbiter} and \textit{Parker Solar Probe}

Author

Long, David M., Green, Lucie M., Pecora, Francesco, Brooks, David H., Strecker, Hanna, Orozco-Suárez, David, Hayes, Laura A., Davies, Emma E., Amerstorfer, Ute V., Mierla, Marilena, Lario, David, Berghmans, David, Zhukov, Andrei N., and Rüdisser, Hannah T.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

Magnetic flux ropes are a key component of coronal mass ejections, forming the core of these eruptive phenomena. However, determining whether a flux rope is present prior to eruption onset and, if so, the rope's handedness and the number of turns that any helical field lines make is difficult without magnetic field modelling or in-situ detection of the flux rope. We present two distinct observations of plasma flows along a filament channel on 4 and 5 September 2022 made using the \textit{Solar Orbiter} spacecraft. Each plasma flow exhibited helical motions in a right-handed sense as the plasma moved from the source active region across the solar disk to the quiet Sun, suggesting that the magnetic configuration of the filament channel contains a flux rope with positive chirality and at least one turn. The length and velocity of the plasma flow increased from the first to the second observation, suggesting evolution of the flux rope, with the flux rope subsequently erupting within $\sim$5~hours of the second plasma flow. The erupting flux rope then passed over the \textit{Parker Solar Probe} spacecraft during its Encounter 13, enabling \textit{in-situ} diagnostics of the structure. Although complex and consistent with the flux rope erupting from underneath the heliospheric current sheet, the \textit{in-situ} measurements support the inference of a right-handed flux rope from remote-sensing observations. These observations provide a unique insight into the eruption and evolution of a magnetic flux rope near the Sun., Comment: 19 pages, 11 figures, accepted for publication in The Astrophysical Journal

Published
2023

5. The Merging of a Coronal Dimming and the Southern Polar Coronal Hole

Author

Ngampoopun, Nawin, Long, David M., Baker, Deborah, Green, Lucie M., Yardley, Stephanie L., James, Alexander W., and To, Andy S. H.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

We report on the merging between the southern polar coronal hole and an adjacent coronal dimming induced by a coronal mass ejection on 2022 March 18, resulting in the merged region persisting for at least 72 hrs. We use remote sensing data from multiple co-observing spacecraft to understand the physical processes during this merging event. The evolution of the merger is examined using Extreme-UltraViolet (EUV) images obtained from the Atmospheric Imaging Assembly onboard the Solar Dynamic Observatory and Extreme Ultraviolet Imager onboard the Solar Orbiter spacecraft. The plasma dynamics are quantified using spectroscopic data obtained from the EUV Imaging Spectrometer onboard Hinode. The photospheric magnetograms from the Helioseismic and Magnetic Imager are used to derive magnetic field properties. To our knowledge, this work is the first spectroscopical analysis of the merging of two open-field structures. We find that the coronal hole and the coronal dimming become indistinguishable after the merging. The upflow speeds inside the coronal dimming become more similar to that of a coronal hole, with a mixture of plasma upflows and downflows observable after the merging. The brightening of bright points and the appearance of coronal jets inside the merged region further imply ongoing reconnection processes. We propose that component reconnection between the coronal hole and coronal dimming fields plays an important role during this merging event, as the footpoint switching resulting from the reconnection allows the coronal dimming to intrude onto the boundary of the southern polar coronal hole., Comment: 17 pages, 8 figures, accepted for publication in The Astrophysical Journal

Published
2023
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6. Slow Solar Wind Connection Science during Solar Orbiter's First Close Perihelion Passage

Author

Yardley, Stephanie L., Owen, Christopher J., Long, David M., Baker, Deborah, Brooks, David H., Polito, Vanessa, Green, Lucie M., Matthews, Sarah, Owens, Mathew, Lockwood, Mike, Stansby, David, James, Alexander W., Valori, Gherado, Giunta, Alessandra, Janvier, Miho, Ngampoopun, Nawin, Mihailescu, Teodora, To, Andy S. H., van Driel-Gesztelyi, Lidia, Demoulin, Pascal, D'Amicis, Raffaella, French, Ryan J., Suen, Gabriel H. H., Roulliard, Alexis P., Pinto, Rui F., Reville, Victor, Watson, Christopher J., Walsh, Andrew P., De Groof, Anik, Williams, David R., Zouganelis, Ioannis, Muller, Daniel, Berghmans, David, Auchere, Frederic, Harra, Louise, Scheuhle, Udo, Barczynski, Krysztof, Buchlin, Eric, Cuadrado, Regina Aznar, Kraaikamp, Emil, Mandal, Sudip, Parenti, Susanna, Peter, Hardi, Rodriguez, Luciano, Schwanitz, Conrad, Smith, Phil, Teriaca, Luca, Verbeeck, Cis, Zhukov, Andrei N., De Pontieu, Bart, Horbury, Tim, Solanki, Sami K., Iniesta, Jose Carlos del Toro, Woch, Joachim, Gandorfer, Achim, Hirzberger, Johann, Suarez, David Orozco, Appourchaux, Thierry, Calchetti, Daniele, Sinjan, Jonas, Kahil, Fatima, Albert, Kinga, Volkmer, Reiner, Carlsson, Mats, Fludra, Andrzej, Hassler, Don, Caldwell, Martin, Fredvik, Terje, Grundy, Tim, Guest, Steve, Haberreiter, Margit, Leeks, Sarah, Pelouze, Gabriel, Plowman, Joseph, Schmutz, Werner, Sidher, Sunil, Thompson, William T., Louarn, Philippe, and Federov, Andrei

Subjects
Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics
Abstract

The Slow Solar Wind Connection Solar Orbiter Observing Plan (Slow Wind SOOP) was developed to utilise the extensive suite of remote sensing and in situ instruments on board the ESA/NASA Solar Orbiter mission to answer significant outstanding questions regarding the origin and formation of the slow solar wind. The Slow Wind SOOP was designed to link remote sensing and in situ measurements of slow wind originating at open-closed field boundaries. The SOOP ran just prior to Solar Orbiter's first close perihelion passage during two remote sensing windows (RSW1 and RSW2) between 2022 March 3-6 and 2022 March 17-22, while Solar Orbiter was at a heliocentric distance of 0.55-0.51 and 0.38-0.34 au from the Sun, respectively. Coordinated observation campaigns were also conducted by Hinode and IRIS. The magnetic connectivity tool was used, along with low latency in situ data, and full-disk remote sensing observations, to guide the target pointing of Solar Orbiter. Solar Orbiter targeted an active region complex during RSW1, the boundary of a coronal hole, and the periphery of a decayed active region during RSW2. Post-observation analysis using the magnetic connectivity tool along with in situ measurements from MAG and SWA/PAS, show that slow solar wind, with velocities between 210 and 600 km/s, arrived at the spacecraft originating from two out of the three of the target regions. The Slow Wind SOOP, despite presenting many challenges, was very successful, providing a blueprint for planning future observation campaigns that rely on the magnetic connectivity of Solar Orbiter., Comment: 24 pages, 10 figures

Published
2023
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7. The magnetic field environment of active region 12673 that produced the energetic particle events of September 2017

Author

Yardley, Stephanie L., Green, Lucie M., James, Alexander W., Stansby, David, and Mihailescu, Teodora

Subjects
Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics
Abstract

Forecasting solar energetic particles (SEPs), and identifying flare/CMEs from active regions (ARs) that will produce SEP events in advance is extremely challenging. We investigate the magnetic field environment of AR 12673, including the AR's magnetic configuration, the surrounding field configuration in the vicinity of the AR, the decay index profile, and the footpoints of Earth-connected magnetic field, around the time of four eruptive events. Two of the eruptive events are SEP-productive (2017 September 4 at 20:00~UT and September 6 at 11:56~UT), while two are not (September 4 at 18:05~UT and September 7 at 14:33~UT). We analysed a range of EUV and white-light coronagraph observations along with potential field extrapolations and find that the CMEs associated with the SEP-productive events either trigger null point reconnection that redirects flare-accelerated particles from the flare site to the Earth-connected field and/or have a significant expansion (and shock formation) into the open Earth-connected field. The rate of change of the decay index with height indicates that the region could produce a fast CME ($v >$ 1500~km~s$^{-1}$), which it did during events two and three. The AR's magnetic field environment, including sites of open magnetic field and null points along with the magnetic field connectivity and propagation direction of the CMEs play an important role in the escape and arrival of SEPs at Earth. Other SEP-productive ARs should be investigated to determine whether their magnetic field environment and CME propagation direction are significant in the escape and arrival of SEPs at Earth., Comment: Accepted in ApJ, 18 pages, 8 Figures, 2 Tables

Published
2022
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8. What determines active region coronal plasma composition?

Author

Mihailescu, Teodora, Baker, Deborah, Green, Lucie M., van Driel-Gesztelyi, Lidia, Long, David M., Brooks, David H., and To, Andy S. H.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

The chemical composition of the solar corona is different from that of the solar photosphere, with the strongest variation being observed in active regions (ARs). Using data from the Extreme Ultraviolet (EUV) Imaging Spectrometer (EIS) on Hinode, we present a survey of coronal elemental composition as expressed in the first ionisation potential (FIP) bias in 28 ARs of different ages and magnetic flux content, which are at different stages in their evolution. We find no correlation between the FIP bias of an AR and its total unsigned magnetic flux or age. However, there is a weak dependence of FIP bias on the evolutionary stage, decreasing from 1.9-2.2 in ARs with spots to 1.5-1.6 in ARs that are at more advanced stages of the decay phase. FIP bias shows an increasing trend with average magnetic flux density up to 200 G but this trend does not continue at higher values. The FIP bias distribution within ARs has a spread between 0.4 and 1. The largest spread is observed in very dispersed ARs. We attribute this to a range of physical processes taking place in these ARs including processes associated with filament channel formation. These findings indicate that, while some general trends can be observed, the processes influencing the composition of an AR are complex and specific to its evolution, magnetic configuration or environment. The spread of FIP bias values in ARs shows a broad match with that previously observed in situ in the slow solar wind., Comment: 20 pages, 14 figures

Published
2022
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9. Evolution of Plasma Composition in an Eruptive Flux Rope

Author

Baker, Deborah, Green, Lucie M., Brooks, David H., Démoulin, Pascal, van-Driel-Gesztelyi, Lidia, Mihailescu, Teodora, To, Andy S. H., Long, David M., Yardley, Stephanie L., Janvier, Miho, and Valori, Gherardo

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

Magnetic flux ropes are bundles of twisted magnetic field enveloping a central axis. They harbor free magnetic energy and can be progenitors of coronal mass ejections (CMEs), but identifying flux ropes on the Sun can be challenging. One of the key coronal observables that has been shown to indicate the presence of a flux rope is a peculiar bright coronal structure called a sigmoid. In this work, we show Hinode EUV Imaging Spectrometer (EIS) observations of sigmoidal active region 10977. We analyze the coronal plasma composition in the active region and its evolution as the sigmoid (flux rope) forms and erupts as a CME. Plasma with photospheric composition was observed in coronal loops close to the main polarity inversion line during episodes of significant flux cancellation, suggestive of the injection of photospheric plasma into these loops driven by photospheric flux cancellation. Concurrently, the increasingly sheared core field contained plasma with coronal composition. As flux cancellation decreased and the sigmoid/flux rope formed, the plasma evolved to an intermediate composition in between photospheric and typical active region coronal compositions. Finally, the flux rope contained predominantly photospheric plasma during and after a failed eruption preceding the CME. The Hence, plasma composition observations of active region 10977 strongly support models of flux rope formation by photospheric flux cancellation forcing magnetic reconnection first at the photospheric level then at the coronal level.

Published
2021
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10. Plasma Upflows Induced by Magnetic Reconnection Above an Eruptive Flux Rope

Author

Baker, Deborah, Mihailescu, Teodora, Demoulin, Pascal, Green, Lucie M., van Driel-Gesztelyi, Lidia, Valori, Gherardo, Brooks, David H., Long, David M., and Janvier, Miho

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

One of the major discoveries of Hinode's Extreme-ultraviolet Imaging Spectrometer (EIS) is the presence of upflows at the edges of active regions. As active regions are magnetically connected to the large-scale field of the corona, these upflows are a likely contributor to the global mass cycle in the corona. Here we examine the driving mechanism(s) of the very strong upflows with velocities in excess of 70 km/s, known as blue-wing asymmetries, observed during the eruption of a flux rope in AR 10977 (eruptive flare SOL2007-12-07T04:50). We use Hinode/EIS spectroscopic observations combined with magnetic-field modeling to investigate the possible link between the magnetic topology of the active region and the strong upflows. A Potential Field Source Surface (PFSS) extrapolation of the large-scale field shows a quadrupolar configuration with a separator lying above the flux rope. Field lines formed by induced reconnection along the separator before and during the flux-rope eruption are spatially linked to the strongest blue-wing asymmetries in the upflow regions. The flows are driven by the pressure gradient created when the dense and hot arcade loops of the active region reconnect with the extended and tenuous loops overlying it. In view of the fact that separator reconnection is a specific form of the more general quasi-separatrix (QSL) reconnection, we conclude that the mechanism driving the strongest upflows is, in fact, the same as the one driving the persistent upflows of approx. 10 - 20 km/s observed in all active regions.

Published
2021
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11. Solar origins of a strong stealth CME detected by Solar Orbiter

Author

O'Kane, Jennifer, Green, Lucie M., Davies, Emma E., Möstl, Christian, Hinterreiter, Jürgen, von Forstner, Johan L. Freiherr, Weiss, Andreas J., Long, David M., and Amerstorfer, Tanja

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

Aims.We aim to locate the origin of a stealth coronal mass ejection (CME) detected in situ by the MAG instrument on board Solar Orbiter, and make connections between the CME observed at the Sun, and the interplanetary CME (ICME) measured in situ. Methods. Remote sensing data are analysed using advanced image processing techniques to identify the source region of the stealth CME, and the global magnetic field at the time of the eruption is examined using Potential Field Source Surface (PFSS) models. The observations of the stealth CME at the Sun are compared with the magnetic field measured by the Solar Orbiter spacecraft, and plasma properties measured by the Wind spacecraft. Results. The source of the CME is found to be a quiet Sun cavity in the northern hemisphere. We find that the stealth CME has a strong magnetic field in situ, despite originating from a quiet Sun region with an extremely weak magnetic field. Conclusions. The interaction of the ICME with its surrounding environment is the likely cause of a higher magnetic field strength measured in situ. Stealth CMEs require multi-wavelength and multi-viewpoint observations in order to confidently locate the source region, however their elusive signatures still pose many problems for space weather forecasting. The findings have implications for Solar Orbiter observing sequences with instruments such as EUI that are designed to capture stealth CMEs, Comment: 6 pages, 7 figures, accepted for publication in A&A

Published
2021
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12. Simulating the Coronal Evolution of Bipolar Active Regions to Investigate the Formation of Flux Ropes

Author

Yardley, Stephanie L., Mackay, Duncan H., and Green, Lucie M.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

The coronal magnetic field evolution of 20 bipolar active regions (ARs) is simulated from their emergence to decay using the time-dependent nonlinear force-free field method of Mackay et al. A time sequence of cleaned photospheric line-of-sight magnetograms, that covers the entire evolution of each AR, is used to drive the simulation. A comparison of the simulated coronal magnetic field with the 171 and 193 A observations obtained by the Solar Dynamics Observatory (SDO)/ Atmospheric Imaging Assembly (AIA), is made for each AR by manual inspection. The results show that it is possible to reproduce the evolution of the main coronal features such as small- and large-scale coronal loops, filaments and sheared structures for 80% of the ARs. Varying the boundary and initial conditions, along with the addition of physical effects such as Ohmic diffusion, hyperdiffusion and a horizontal magnetic field injection at the photosphere, improves the match between the observations and simulated coronal evolution by 20%. The simulations were able to reproduce the build-up to eruption for 50% of the observed eruptions associated with the ARs. The mean unsigned time difference between the eruptions occurring in the observations compared to the time of eruption onset in the simulations was found to be ~5 hrs. The simulations were particularly successful in capturing the build-up to eruption for all four eruptions that originated from the internal polarity inversion line of the ARs. The technique was less successful in reproducing the onset of eruptions that originated from the periphery of ARs and large-scale coronal structures. For these cases global, rather than local, nonlinear force-free field models must be used. While the technique has shown some success, eruptions that occur in quick succession are difficult to reproduce by this method and future iterations of the model need to address this., Comment: 32 pages, 8 figures, accepted for publication

Published
2020
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13. The Magnetic Environment of a Stealth Coronal Mass Ejection

Author

O'Kane, Jennifer, Mac Cormack, Cecilia, Mandrini, Cristina H., Démoulin, Pascal, Green, Lucie M., Long, David M., and Valori, Gherardo

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

Interest in stealth coronal mass ejections (CMEs) is increasing due to their relatively high occurrence rate and space weather impact. However, typical CME signatures such as extreme-ultraviolet dimmings and post-eruptive arcades are hard to identify and require extensive image processing techniques. These weak observational signatures mean that little is currently understood about the physics of these events. We present an extensive study of the magnetic field configuration in which the stealth CME of 3 March 2011 occurred. Three distinct episodes of flare ribbon formation are observed in the stealth CME source active region (AR). Two occurred prior to the eruption and suggest the occurrence of magnetic reconnection that builds the structure which will become eruptive. The third occurs in a time close to the eruption of a cavity that is observed in STEREO-B 171A data; this subsequently becomes part of the propagating CME observed in coronagraph data. We use both local (Cartesian) and global (spherical) models of the coronal magnetic field, which are complemented and verified by the observational analysis. We find evidence of a coronal null point, with field lines computed from its neighbourhood connecting the stealth CME source region to two ARs in the northern hemisphere. We conclude that reconnection at the null point aids the eruption of the stealth CME by removing field that acted to stabilise the pre-eruptive structure. This stealth CME, despite its weak signatures, has the main characteristics of other CMEs, and its eruption is driven by similar mechanisms., Comment: 15 pages, 12 figures, accepted for publication in The Astrophysical Journal

Published
2020
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14. Prediction of solar energetic events impacting space weather conditions

Author

Georgoulis, Manolis K., Yardley, Stephanie L., Guerra, Jordan A., Murray, Sophie A., Ahmadzadeh, Azim, Anastasiadis, Anastasios, Angryk, Rafal, Aydin, Berkay, Banerjee, Dipankar, Barnes, Graham, Bemporad, Alessandro, Benvenuto, Federico, Bloomfield, D. Shaun, Bobra, Monica, Campi, Cristina, Camporeale, Enrico, DeForest, Craig E., Emslie, A. Gordon, Falconer, David, Feng, Li, Gan, Weiqun, Green, Lucie M., Guastavino, Sabrina, Hapgood, Mike, Kempton, Dustin, Kitiashvili, Irina, Kontogiannis, Ioannis, Korsos, Marianna B., Leka, K.D., Massa, Paolo, Massone, Anna Maria, Nandy, Dibyendu, Nindos, Alexander, Papaioannou, Athanasios, Park, Sung-Hong, Patsourakos, Spiros, Piana, Michele, Rawafi, Nour E., Sadykov, Viacheslav M., Toriumi, Shin, Vourlidas, Angelos, Wang, Haimin, L. Wang, Jason T., Whitman, Kathryn, Yan, Yihua, and Zhukov, Andrei N.

Published
2024
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15. A new trigger mechanism for coronal mass ejections: the role of confined flares and photospheric motions in the formation of hot flux ropes

Author

James, Alexander W, Green, Lucie M, van Driel-Gesztelyi, Lidia, and Valori, Gherardo

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

Context: Many previous studies have shown that the magnetic precursor of a coronal mass ejection (CME) takes the form of a magnetic flux rope, and a subset of them have become known as `hot flux ropes' due to their emission signatures in $\sim$10 MK plasma. Aims: We seek to identify the processes by which these hot flux ropes form, with a view of developing our understanding of CMEs and thereby improving space weather forecasts. Methods: Extreme-ultraviolet observations were used to identify five pre-eruptive hot flux ropes in the solar corona and study how they evolved. Confined flares were observed in the hours and days before each flux rope erupted, and these were used as indicators of episodic bursts of magnetic reconnection by which each flux rope formed. The evolution of the photospheric magnetic field was observed during each formation period to identify the process(es) that enabled magnetic reconnection to occur in the $\beta<1$ corona and form the flux ropes. Results: The confined flares were found to be homologous events and suggest flux rope formation times that range from 18 hours to 5 days. Throughout these periods, fragments of photospheric magnetic flux were observed to orbit around each other in sunspots where the flux ropes had a footpoint. Active regions with right-handed (left-handed) twisted magnetic flux exhibited clockwise (anticlockwise) orbiting motions, and right-handed (left-handed) flux ropes formed. Conclusions: We infer that the orbital motions of photospheric magnetic flux fragments about each other bring magnetic flux tubes together in the corona, enabling component reconnection that forms a magnetic flux rope above a flaring arcade. This represents a novel trigger mechanism for solar eruptions and should be considered when predicting solar magnetic activity., Comment: Accepted for publication in Astronomy & Astrophysics. 14 pages, 16 figures, 2 tables

Published
2020
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16. Understanding the plasma and magnetic field evolution of a filament using observations and Nonlinear force-free field modelling

Author

Yardley, Stephanie L., Savcheva, Antonia, Green, Lucie M., van Driel-Gesztelyi, Lidia, Long, David, Williams, David R., and Mackay, Duncan H.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

We present observations and magnetic field models of an intermediate filament present on the Sun in August 2012, associated with a polarity inversion line that extends from AR 11541 in the east into the quiet sun at its western end. A combination of SDO/AIA, SDO/HMI, and GONG H alpha data allow us to analyse the structure and evolution of the filament from 2012 August 4 23:00 UT to 2012 August 6 08:00 UT when the filament was in equilibrium. By applying the flux rope insertion method, nonlinear force-free field models of the filament are constructed using SDO/HMI line-of-sight magnetograms as the boundary condition at the two times given above. Guided by observed filament barbs, both modelled flux ropes are split into three sections each with a different value of axial flux to represent the non-uniform photospheric field distribution. The flux in the eastern section of the rope increases by 4$\times$10$^{20}$ Mx between the two models, which is in good agreement with the amount of flux cancelled along the internal PIL of AR 11541, calculated to be 3.2$\times$10$^{20}$ Mx. This suggests that flux cancellation builds flux into the filament's magnetic structure. Additionally, the number of field line dips increases between the two models in the locations where flux cancellation, the formation of new filament threads and growth of the filament is observed. This suggests that flux cancellation associated with magnetic reconnection forms concave-up magnetic field that lifts plasma into the filament. During this time, the free magnetic energy in the models increases by 0.2$\times$10$^{31}$ ergs., Comment: 17 pages, 10 figures

Published
2019
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17. Transient Inverse-FIP Plasma Composition Evolution within a Confined Solar Flare

Author

Baker, Deborah, van Driel-Gesztelyi, Lidia, Brooks, David H., Valori, Gherardo, James, Alexander W., Laming, J. Martin, Long, David M., Demoulin, Pascal, Green, Lucie M., Matthews, Sarah A., Olah, Katalin, and Kovari, Zsolt

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

Understanding elemental abundance variations in the solar corona provides an insight into how matter and energy flow from the chromosphere into the heliosphere. Observed variations depend on the first ionization potential (FIP) of the main elements of the Sun's atmosphere. High-FIP elements (>10 eV) maintain photospheric abundances in the corona, whereas low-FIP elements have enhanced abundances. Conversely, inverse FIP (IFIP) refers to the enhancement of high-FIP or depletion of low-FIP elements. We use spatially resolved spectroscopic observations, specifically the Ar XIV/Ca XIV intensity ratio, from Hinode's Extreme-ultraviolet Imaging Spectrometer to investigate the distribution and evolution of plasma composition within two confined flares in a newly emerging, highly sheared active region. During the decay phase of the first flare, patches above the flare ribbons evolve from the FIP to the IFIP effect, while the flaring loop tops show a stronger FIP effect. The patch and loop compositions then evolve toward the pre-flare basal state. We propose an explanation of how flaring in strands of highly sheared emerging magnetic fields can lead to flare-modulated IFIP plasma composition over coalescing umbrae which are crossed by flare ribbons. Subsurface reconnection between the coalescing umbrae leads to the depletion of low-FIP elements as a result of an increased wave flux from below. This material is evaporated when the flare ribbons cross the umbrae. Our results are consistent with the ponderomotive fractionation model (Laming2015) for the creation of IFIP-biased plasma., Comment: 18 pages, 9 figures

Published
2019
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18. Coronal Magnetic Structure of Earthbound CMEs and In situ Comparison

Author

Palmerio, Erika, Kilpua, Emilia K. J., Möstl, Christian, Bothmer, Volker, James, Alexander W., Green, Lucie M., Isavnin, Alexey, Davies, Jackie A., and Harrison, Richard A.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

Predicting the magnetic field within an Earth-directed coronal mass ejection (CME) well before its arrival at Earth is one of the most important issues in space weather research. In this article, we compare the intrinsic flux rope type, i.e. the CME orientation and handedness during eruption, with the in situ flux rope type for 20 CME events that have been uniquely linked from Sun to Earth through heliospheric imaging. Our study shows that the intrinsic flux rope type can be estimated for CMEs originating from different source regions using a combination of indirect proxies. We find that only 20% of the events studied match strictly between the intrinsic and in situ flux rope types. The percentage rises to 55% when intermediate cases (where the orientation at the Sun and/or in situ is close to 45{\deg}) are considered as a match. We also determine the change in the flux rope tilt angle between the Sun and Earth. For the majority of the cases, the rotation is several tens of degrees, whilst 35% of the events change by more than 90{\deg}. While occasionally the intrinsic flux rope type is a good proxy for the magnetic structure impacting Earth, our study highlights the importance of capturing the CME evolution for space weather forecasting purposes. Moreover, we emphasize that determination of the intrinsic flux rope type is a crucial input for CME forecasting models., Comment: 27 pages, 6 figures, accepted for publication in Space Weather

Published
2018
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19. An Observationally-Constrained Model of a Flux Rope that Formed in the Solar Corona

Author

James, Alexander W., Valori, Gherardo, Green, Lucie M., Liu, Yang, Cheung, Mark C. M., Guo, Yang, and van Driel-Gesztelyi, Lidia

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

Coronal mass ejections (CMEs) are large-scale eruptions of plasma from the coronae of stars. Understanding the plasma processes involved in CME initiation has applications to space weather forecasting and laboratory plasma experiments. James et al. (Sol. Phys. 292, 71, 2017) used EUV observations to conclude that a magnetic flux rope formed in the solar corona above NOAA Active Region 11504 before it erupted on 14 June 2012 (SOL2012-06-14). In this work, we use data from the Solar Dynamics Observatory to model the coronal magnetic field of the active region one hour prior to eruption using a nonlinear force-free field extrapolation, and find a flux rope reaching a maximum height of 150 Mm above the photosphere. Estimations of the average twist of the strongly asymmetric extrapolated flux rope are between 1.35 and 1.88 turns, depending on the choice of axis, although the erupting structure was not observed to kink. The decay index near the apex of the axis of the extrapolated flux rope is comparable to typical critical values required for the onset of the torus instability, so we suggest that the torus instability drove the eruption., Comment: 8 pages, 5 figures

Published
2018
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20. Simulating the Coronal Evolution of AR 11437 using SDO/HMI Magnetograms

Author

Yardley, Stephanie L., Mackay, Duncan H., and Green, Lucie M.

Subjects
Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics
Abstract

The coronal magnetic field evolution of AR 11437 is simulated by applying the magnetofrictional relaxation technique of Mackay et al. (2011). A sequence of photospheric line-of-sight magnetograms produced by SDO/HMI are used to drive the simulation and continuously evolve the coronal magnetic field of the active region through a series of non-linear force-free equilibria. The simulation is started during the first stages of the active region emergence so that its full evolution from emergence to decay can be simulated. A comparison of the simulation results with SDO/AIA observations show that many aspects of the active region's observed coronal evolution are reproduced. In particular, it shows the presence of a flux rope, which forms at the same location as sheared coronal loops in the observations. The observations show that eruptions occur on 2012 March 17 at 05:09 UT and 10:45 UT and on 2012 March 20 at 14:31 UT. The simulation reproduces the first and third eruption, with the simulated flux rope erupting roughly 1 and 10 hours before the observed ejections, respectively. A parameter study is conducted where the boundary and initial conditions are varied along with the physical effects of Ohmic diffusion, hyperdiffusion and an additional injection of helicity. When comparing the simulations, the evolution of the magnetic field, free magnetic energy, relative helicity and flux rope eruption timings do not change significantly. This indicates that the key element in reproducing the coronal evolution of AR 11437 is the use of line-of-sight magnetograms to drive the evolution of the coronal magnetic field., Comment: 18 pages, 13 figures, accepted in ApJ

Published
2017
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21. The 17 February 2013 sunquake in the context of the active region's magnetic field configuration

Author

Green, Lucie M., Valori, Gherardo, Zuccarello, Francesco P., Zharkov, Sergei, Matthews, Sarah, and Guglielmino, Salvo L.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

Sunquakes are created by the hydrodynamic response of the lower atmosphere to a sudden deposition of energy and momentum. In this study we investigate a sunquake that occurred in NOAA active region 11675 on 17 February 2013. Observations of the corona, chromosphere and photosphere are brought together for the first time with a non-linear force-free model of the active region's magnetic field in order to probe the magnetic environment in which the sunquake was initiated. We find that the sunquake was associated with the destabilization of a flux rope and an associated M-class GOES flare. Active region 11675 was in its emergence phase at the time of the sunquake and photospheric motions caused by the emergence heavily modified the flux rope and its associated quasi-separatrix layers, eventually triggering the flux rope's instability. The flux rope was surrounded by an extended envelope of field lines rooted in a small area at the approximate position of the sunquake. We argue that the configuration of the envelope, by interacting with the expanding flux rope, created a "magnetic lens" that may have focussed energy in one particular location the photosphere, creating the necessary conditions for the initiation of the sunquake., Comment: 20 pages, 16 Figures. Some figures have lower resolution than published version

Published
2017
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22. Determining the Intrinsic CME Flux Rope Type Using Remote-sensing Solar Disk Observations

Author

Palmerio, Erika, Kilpua, Emilia K. J., James, Alexander W., Green, Lucie M., Pomoell, Jens, Isavnin, Alexey, and Valori, Gherardo

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

A key aim in space weather research is to be able to use remote-sensing observations of the solar atmosphere to extend the lead time of predicting the geoeffectiveness of a coronal mass ejection (CME). In order to achieve this, the magnetic structure of the CME as it leaves the Sun must be known. In this article we address this issue by developing a method to determine the intrinsic flux rope type of a CME solely from solar disk observations. We use several well known proxies for the magnetic helicity sign, the axis orientation, and the axial magnetic field direction to predict the magnetic structure of the interplanetary flux rope. We present two case studies: the 2 June 2011 and the 14 June 2012 CMEs. Both of these events erupted from an active region and, despite having clear in situ counterparts, their eruption characteristics were relatively complex. The first event was associated with an active region filament that erupted in two stages, while for the other event the eruption originated from a relatively high coronal altitude and the source region did not feature the presence of a filament. Our magnetic helicity sign proxies include the analysis of magnetic tongues, soft X-ray and/or EUV sigmoids, coronal arcade skew, filament emission and absorption threads, and filament rotation. Since the inclination of the post-eruption arcades was not clear, we use the tilt of the polarity inversion line to determine the flux rope axis orientation, and coronal dimmings to determine the flux rope footpoints and, therefore, the direction of the axial magnetic field. The comparison of the estimated intrinsic flux rope structure to in situ observations at the Lagrangian point L1 indicated a good agreement with the predictions. Our results highlight the flux rope type determination techniques that are particularly useful for active region eruptions, where most geoeffective CMEs originate., Comment: 24 pages, 7 figures, accepted for publication in Solar Physics

Published
2017
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23. Spectroscopic Signatures Related to a Sunquake

Author

Matthews, Sarah A., Harra, Louise K., Zharkov, Sergei, and Green, Lucie M.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

The presence of flare related acoustic emission (sunquakes) in some flares represents a severe challenge to our current understanding of flare energy transport processes. We present a comparison of new spectral observations from Hinode's EUV imaging Spectrometer (EIS) and the Interface Region Imaging Spectrograph (IRIS) of the atmosphere above a sunquake, and compare them to the spectra observed in a part of the flaring region with no acoustic signature. Evidence for the sunquake is determined using both time-distance and acoustic holography methods, and we find that, unlike many previous sunquake detections, the signal is rather dispersed, but that the time-distance and 6 and 7 mHz sources converge at the same spatial location. We also see some evidence for different evolution at different frequencies, with an earlier peak at 7 mHz than at 6 mHz. Using spectroscopic measurements we find that in this location at the time of the 7 mHz peak the spectral emission is significantly more intense, shows larger velocity shifts and substantially broader profiles than in the location with no sunquake, and that there is a good correlation between blue-shifted, hot coronal, hard X-ray (HXR) and red-shifted chromospheric emission, consistent with the idea of a strong downward motion driven by rapid heating by non-thermal electrons and the formation of chromospheric shocks. Exploiting the diagnostic potential of the Mg II triplet lines, we also find evidence for a single, large temperature increase deep in the atmosphere, consistent with this scenario. The time of the 6 mHz and time-distance peak signal coincides with a secondary peak in the energy release process, but in this case we find no evidence of HXR emission in the quake location, but very broad spectral lines, strongly shifted to the red, indicating the possible presence of a significant flux of downward propagating Alfven waves., Comment: 39 pages, 13 figures, accepted for publication in ApJ

Published
2015
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26. Observations of flux rope formation prior to coronal mass ejections

Author

Green, Lucie M. and Kliem, Bernhard

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

Understanding the magnetic configuration of the source regions of coronal mass ejections (CMEs) is vital in order to determine the trigger and driver of these events. Observations of four CME productive active regions are presented here, which indicate that the pre-eruption magnetic configuration is that of a magnetic flux rope. The flux ropes are formed in the solar atmosphere by the process known as flux cancellation and are stable for several hours before the eruption. The observations also indicate that the magnetic structure that erupts is not the entire flux rope as initially formed, raising the question of whether the flux rope is able to undergo a partial eruption or whether it undergoes a transition in specific flux rope configuration shortly before the CME., Comment: Proc. IAU Symp. 300 "Nature of prominences and their role in space weather", in press

Published
2013
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27. Temperature Tomography of a Coronal Sigmoid Supporting the Gradual Formation of a Flux Rope

Author

Tripathi, Durgesh, Kliem, Bernhard, Mason, Helen E., Young, Peter, and Green, Lucie M.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

Multi-wavelength observations of a sigmoidal (S-shaped) solar coronal source by the EUV Imaging Spectrometer and the X-ray Telescope aboard the Hinode spacecraft and by the EUV Imager aboard STEREO are reported. The data reveal the coexistence of a pair of J-shaped hot arcs at temperatures T>2 MK with an S-shaped structure at somewhat lower temperatures T~1.3 MK. The middle section of the S-shaped structure runs along the polarity inversion line of the photospheric field, bridging the gap between the arcs. Flux cancellation occurs at the same location in the photosphere. The sigmoid forms in the gradual decay phase of the active region, which does not experience an eruption. These findings correspond to the expected signatures of a flux rope forming, or being augmented, gradually by a topology transformation inside a magnetic arcade. In such a transformation, the plasma on newly formed helical field lines in the outer flux shell of the rope (S-shaped in projection) is expected to enter a cooling phase once the reconnection of their parent field line pairs (double-J shaped in projection) is complete. Thus, the data support the conjecture that flux ropes can exist in the corona prior to eruptive activity., Comment: 15 pages, 5 figures, Accepted for publication in ApJ Letters

Published
2009
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29. CMAG: A Mission to Study and Monitor the Inner Corona Magnetic Field

Author

Orozco Suárez, David, primary, del Toro Iniesta, Jose Carlos, additional, Bailén Martínez, Francisco Javier, additional, Balaguer Jiménez, María, additional, Álvarez García, Daniel, additional, Serrano, Daniel, additional, Peñin, Luis F., additional, Vázquez-Ramos, Alicia, additional, Bellot Rubio, Luis Ramón, additional, Atienzar, Julia, additional, Pérez Grande, Isabel, additional, Torralbo Gimeno, Ignacio, additional, Sanchis Kilders, Esteban, additional, Gasent Blesa, José Luis, additional, Hernández Expósito, David, additional, Ruiz Cobo, Basilio, additional, Trujillo Bueno, Javier, additional, Erdélyi, Robertus, additional, Davies, Jackie A., additional, Green, Lucie M., additional, Matthews, Sarah A., additional, Long, David M., additional, Mathioudakis, Michail, additional, Kintziger, Christian, additional, Leenaarts, Jorrit, additional, Fineschi, Silvano, additional, and Scullion, Eamon, additional

Published
2023
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31. The Eruption of a Magnetic Flux Rope Observed by Solar Orbiter and Parker Solar Probe

Author

Long, David M., primary, Green, Lucie M., additional, Pecora, Francesco, additional, Brooks, David H., additional, Strecker, Hanna, additional, Orozco-Suárez, David, additional, Hayes, Laura A., additional, Davies, Emma E., additional, Amerstorfer, Ute V., additional, Mierla, Marilena, additional, Lario, David, additional, Berghmans, David, additional, Zhukov, Andrei N., additional, and Rüdisser, Hannah T., additional

Published
2023
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32. Slow Solar Wind Connection Science during Solar Orbiter’s First Close Perihelion Passage

Author

Yardley, Stephanie L., primary, Owen, Christopher J., additional, Long, David M., additional, Baker, Deborah, additional, Brooks, David H., additional, Polito, Vanessa, additional, Green, Lucie M., additional, Matthews, Sarah, additional, Owens, Mathew, additional, Lockwood, Mike, additional, Stansby, David, additional, James, Alexander W., additional, Valori, Gherardo, additional, Giunta, Alessandra, additional, Janvier, Miho, additional, Ngampoopun, Nawin, additional, Mihailescu, Teodora, additional, To, Andy S. H., additional, van Driel-Gesztelyi, Lidia, additional, Démoulin, Pascal, additional, D’Amicis, Raffaella, additional, French, Ryan J., additional, Suen, Gabriel H. H., additional, Rouillard, Alexis P., additional, Pinto, Rui F., additional, Réville, Victor, additional, Watson, Christopher J., additional, Walsh, Andrew P., additional, De Groof, Anik, additional, Williams, David R., additional, Zouganelis, Ioannis, additional, Müller, Daniel, additional, Berghmans, David, additional, Auchère, Frédéric, additional, Harra, Louise, additional, Schuehle, Udo, additional, Barczynski, Krysztof, additional, Buchlin, Éric, additional, Cuadrado, Regina Aznar, additional, Kraaikamp, Emil, additional, Mandal, Sudip, additional, Parenti, Susanna, additional, Peter, Hardi, additional, Rodriguez, Luciano, additional, Schwanitz, Conrad, additional, Smith, Phil, additional, Teriaca, Luca, additional, Verbeeck, Cis, additional, Zhukov, Andrei N., additional, De Pontieu, Bart, additional, Horbury, Tim, additional, Solanki, Sami K., additional, del Toro Iniesta, Jose Carlos, additional, Woch, Joachim, additional, Gandorfer, Achim, additional, Hirzberger, Johann, additional, Súarez, David Orozco, additional, Appourchaux, Thierry, additional, Calchetti, Daniele, additional, Sinjan, Jonas, additional, Kahil, Fatima, additional, Albert, Kinga, additional, Volkmer, Reiner, additional, Carlsson, Mats, additional, Fludra, Andrzej, additional, Hassler, Don, additional, Caldwell, Martin, additional, Fredvik, Terje, additional, Grundy, Tim, additional, Guest, Steve, additional, Haberreiter, Margit, additional, Leeks, Sarah, additional, Pelouze, Gabriel, additional, Plowman, Joseph, additional, Schmutz, Werner, additional, Sidher, Sunil, additional, Thompson, William T., additional, Louarn, Philippe, additional, and Federov, Andrei, additional

Published
2023
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34. CMAG : A Mission to Study and Monitor the Inner Corona Magnetic Field

Author

Suarez, David Orozco, Iniesta, Jose Carlos del Toro, Martinez, Francisco Javier Bailen, Jimenez, Maria Balaguer, Garcia, Daniel Alvarez, Serrano, Daniel, Penin, Luis F., Vazquez-Ramos, Alicia, Rubio, Luis Ramon Bellot, Atienzar, Julia, Grande, Isabel Perez, Gimeno, Ignacio Torralbo, Kilders, Esteban Sanchis, Blesa, Jose Luis Gasent, Exposito, David Hernandez, Cobo, Basilio Ruiz, Bueno, Javier Trujillo, Erdelyi, Robertus, Davies, Jackie A., Green, Lucie M., Matthews, Sarah A., Long, David M., Mathioudakis, Michail, Kintziger, Christian, Leenaarts, Jorrit, Fineschi, Silvano, Scullion, Eamon, Suarez, David Orozco, Iniesta, Jose Carlos del Toro, Martinez, Francisco Javier Bailen, Jimenez, Maria Balaguer, Garcia, Daniel Alvarez, Serrano, Daniel, Penin, Luis F., Vazquez-Ramos, Alicia, Rubio, Luis Ramon Bellot, Atienzar, Julia, Grande, Isabel Perez, Gimeno, Ignacio Torralbo, Kilders, Esteban Sanchis, Blesa, Jose Luis Gasent, Exposito, David Hernandez, Cobo, Basilio Ruiz, Bueno, Javier Trujillo, Erdelyi, Robertus, Davies, Jackie A., Green, Lucie M., Matthews, Sarah A., Long, David M., Mathioudakis, Michail, Kintziger, Christian, Leenaarts, Jorrit, Fineschi, Silvano, and Scullion, Eamon

Abstract

Measuring magnetic fields in the inner corona, the interface between the solar chromosphere and outer corona, is of paramount importance if we aim to understand the energetic transformations taking place there, and because it is at the origin of processes that lead to coronal heating, solar wind acceleration, and of most of the phenomena relevant to space weather. However, these measurements are more difficult than mere imaging because polarimetry requires differential photometry. The coronal magnetograph mission (CMAG) has been designed to map the vector magnetic field, line-of-sight velocities, and plane-of-the-sky velocities of the inner corona with unprecedented spatial and temporal resolutions from space. This will be achieved through full vector spectropolarimetric observations using a coronal magnetograph as the sole instrument on board a spacecraft, combined with an external occulter installed on another spacecraft. The two spacecraft will maintain a formation flight distance of 430 m for coronagraphic observations, which requires a 2.5 m occulter disk radius. The mission will be preferentially located at the Lagrangian L5 point, offering a significant advantage for solar physics and space weather research. Existing ground-based instruments face limitations such as atmospheric turbulence, solar scattered light, and long integration times when performing coronal magnetic field measurements. CMAG overcomes these limitations by performing spectropolarimetric measurements from space with an external occulter and high-image stability maintained over time. It achieves the necessary sensitivity and offers a spatial resolution of 2.5 '' and a temporal resolution of approximately one minute, in its nominal mode, covering the range from 1.02 solar radii to 2.5 radii. CMAG relies on proven European technologies and can be adapted to enhance any other solar mission, offering potential significant advancements in coronal physics and space weather modeling and monitoring.

Published
2023
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35. CMAG: A Mission to Study and Monitor the Inner Corona Magnetic Field

Author

Orozco Suárez, David, Toro Iniesta, J. C. del, Bailén Martínez, Francisco Javier, Balaguer Jiménez, María, Álvarez García, Daniel, Serrano, Daniel, Peñín, F., Vázquez Ramos, Alicia, Bellot Rubio, Luis Ramón, Atiénzar, Julia, Pérez Grande, María Isabel, Torralbo Gimeno, Ignacio, Sanchis Kilders, Esteban, Gasent Blesa, J. L., Hernández Expósito, David, Ruiz Cobo, Basilio, Trujillo Bueno, Javier, Robertus, Erdelyi, Davies, Jackie A., Green, Lucie M., Matthews, Sarah A., Long, David M., Kintziger, Christian, Leenaarts, Jorrit, Fineschi, Silvano, Scullion, Eamon, Orozco Suárez, David, Toro Iniesta, J. C. del, Bailén Martínez, Francisco Javier, Balaguer Jiménez, María, Álvarez García, Daniel, Serrano, Daniel, Peñín, F., Vázquez Ramos, Alicia, Bellot Rubio, Luis Ramón, Atiénzar, Julia, Pérez Grande, María Isabel, Torralbo Gimeno, Ignacio, Sanchis Kilders, Esteban, Gasent Blesa, J. L., Hernández Expósito, David, Ruiz Cobo, Basilio, Trujillo Bueno, Javier, Robertus, Erdelyi, Davies, Jackie A., Green, Lucie M., Matthews, Sarah A., Long, David M., Kintziger, Christian, Leenaarts, Jorrit, Fineschi, Silvano, and Scullion, Eamon

Abstract

Measuring magnetic fields in the inner corona, the interface between the solar chromosphere and outer corona, is of paramount importance if we aim to understand the energetic transformations taking place there, and because it is at the origin of processes that lead to coronal heating, solar wind acceleration, and of most of the phenomena relevant to space weather. However, these measurements are more difficult than mere imaging because polarimetry requires differential photometry. The coronal magnetograph mission (CMAG) has been designed to map the vector magnetic field, line-of-sight velocities, and plane-of-the-sky velocities of the inner corona with unprecedented spatial and temporal resolutions from space. This will be achieved through full vector spectropolarimetric observations using a coronal magnetograph as the sole instrument on board a spacecraft, combined with an external occulter installed on another spacecraft. The two spacecraft will maintain a formation flight distance of 430 m for coronagraphic observations, which requires a 2.5 m occulter disk radius. The mission will be preferentially located at the Lagrangian L5 point, offering a significant advantage for solar physics and space weather research. Existing ground-based instruments face limitations such as atmospheric turbulence, solar scattered light, and long integration times when performing coronal magnetic field measurements. CMAG overcomes these limitations by performing spectropolarimetric measurements from space with an external occulter and high-image stability maintained over time. It achieves the necessary sensitivity and offers a spatial resolution of 2.5 '' and a temporal resolution of approximately one minute, in its nominal mode, covering the range from 1.02 solar radii to 2.5 radii. CMAG relies on proven European technologies and can be adapted to enhance any other solar mission, offering potential significant advancements in coronal physics and space weather modeling and monitoring.

Published
2023

36. The Solar Particle Acceleration Radiation and Kinetics (SPARK) Mission Concept

Author

Reid, Hamish A. S., Musset, Sophie, Ryan, Daniel F., Andretta, Vincenzo, Auchère, Frédéric, Baker, Deborah, Benvenuto, Federico, Browning, Philippa, Buchlin, Éric, Calcines Rosario, Ariadna, Christe, Steven D., Corso, Alain Jody, Dahlin, Joel, Dalla, Silvia, Del Zanna, Giulio, Denker, Carsten, Dudík, Jaroslav, Erdélyi, Robertus, Ermolli, Ilaria, Fletcher, Lyndsay, Fludra, Andrzej, Green, Lucie M., Gordovskyy, Mykola, Guglielmino, Salvo L., Hannah, Iain, Harrison, Richard, Hayes, Laura A., Inglis, Andrew R., Jeffrey, Natasha L. S., Kašparová, Jana, Kerr, Graham S., Kintziger, Christian, Kontar, Eduard P., Krucker, Säm, Laitinen, Timo, Laurent, Philippe, Limousin, Olivier, Long, David M., Maloney, Shane A., Massa, Paolo, Massone, Anna Maria, Matthews, Sarah, Mrozek, Tomasz, Nakariakov, Valery M., Parenti, Susanna, Piana, Michele, Polito, Vanessa, Pesce-Rollins, Melissa, Romano, Paolo, Rouillard, Alexis P., Sasso, Clementina, Shih, Albert Y., Stęślicki, Marek, Orozco Suárez, David, Teriaca, Luca, Verma, Meetu, Veronig, Astrid M., Vilmer, Nicole, Vocks, Christian, Warmuth, Alexander, Reid, Hamish A. S., Musset, Sophie, Ryan, Daniel F., Andretta, Vincenzo, Auchère, Frédéric, Baker, Deborah, Benvenuto, Federico, Browning, Philippa, Buchlin, Éric, Calcines Rosario, Ariadna, Christe, Steven D., Corso, Alain Jody, Dahlin, Joel, Dalla, Silvia, Del Zanna, Giulio, Denker, Carsten, Dudík, Jaroslav, Erdélyi, Robertus, Ermolli, Ilaria, Fletcher, Lyndsay, Fludra, Andrzej, Green, Lucie M., Gordovskyy, Mykola, Guglielmino, Salvo L., Hannah, Iain, Harrison, Richard, Hayes, Laura A., Inglis, Andrew R., Jeffrey, Natasha L. S., Kašparová, Jana, Kerr, Graham S., Kintziger, Christian, Kontar, Eduard P., Krucker, Säm, Laitinen, Timo, Laurent, Philippe, Limousin, Olivier, Long, David M., Maloney, Shane A., Massa, Paolo, Massone, Anna Maria, Matthews, Sarah, Mrozek, Tomasz, Nakariakov, Valery M., Parenti, Susanna, Piana, Michele, Polito, Vanessa, Pesce-Rollins, Melissa, Romano, Paolo, Rouillard, Alexis P., Sasso, Clementina, Shih, Albert Y., Stęślicki, Marek, Orozco Suárez, David, Teriaca, Luca, Verma, Meetu, Veronig, Astrid M., Vilmer, Nicole, Vocks, Christian, and Warmuth, Alexander

Abstract

Particle acceleration is a fundamental process arising in many astrophysical objects, including active galactic nuclei, black holes, neutron stars, gamma-ray bursts, accretion disks, solar and stellar coronae, and planetary magnetospheres. Its ubiquity means energetic particles permeate the Universe and influence the conditions for the emergence and continuation of life. In our solar system, the Sun is the most energetic particle accelerator, and its proximity makes it a unique laboratory in which to explore astrophysical particle acceleration. However, despite its importance, the physics underlying solar particle acceleration remain poorly understood. The SPARK mission will reveal new discoveries about particle acceleration through a uniquely powerful and complete combination of γ-ray, X-ray, and EUV imaging and spectroscopy at high spectral, spatial, and temporal resolutions. SPARK’s instruments will provide a step change in observational capability, enabling fundamental breakthroughs in our understanding of solar particle acceleration and the phenomena associated with it, such as the evolution of solar eruptive events. By providing essential diagnostics of the processes that drive the onset and evolution of solar flares and coronal mass ejections, SPARK will elucidate the underlying physics of space weather events that can damage satellites and power grids, disrupt telecommunications and GPS navigation, and endanger astronauts in space. The prediction of such events and the mitigation of their potential impacts are crucial in protecting our terrestrial and space-based infrastructure.

Published
2023

41. Solar origins of a strong stealth CME detected by Solar Orbiter

Author

O’Kane, Jennifer, primary, Green, Lucie M., additional, Davies, Emma E., additional, Möstl, Christian, additional, Hinterreiter, Jürgen, additional, Freiherr von Forstner, Johan L., additional, Weiss, Andreas J., additional, Long, David M., additional, and Amerstorfer, Tanja, additional

Published
2021
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42. Mini statistical study of chemical composition in solar active regions

Author

Mihailescu, Teodora, Baker, Deborah, Van Driel-Gesztelyi, Lidia, Green, Lucie M., Brooks, David H., and Long, David

Subjects
Computer Science::Computer Science and Game Theory, plasma composition, FIP bias, active region evolution, Astrophysics::Solar and Stellar Astrophysics
Abstract

In the solar corona, elements with a low first ionisation potential (FIP) have been observed to have an increased abundance compared to the photosphere. This phenomenon is known as the FIP effect and the degree of enhancement is measured using the FIP bias parameter. In this study, the first full Sun FIP bias map, taken between 16-18 January 2013, is analysed to produce a mini statistical study of metal enhancement in the corona in the 9 active regions present on the surface of the Sun at the time. Results showed that the FIP bias is linked to three main factors. First, FIP bias was observed to increase with the total magnetic flux of the active region. Second, the following polarity was observed to have a higher FIP bias than the leading polarity. This could be explained by the magnetic field being more dispersed in the following than the leading polarity. Third, the FIP bias dependence with magnetic flux density was found to increase with magnetic flux density in the low magnetic flux density region, but then decrease in the regions of very concentrated magnetic field, i.e. regions with sunspots.

Published
2021
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44. Solar Particle Acceleration Radiation and Kinetics (SPARK): A mission to understand the nature of particle acceleration

Author

Matthews, Sarah A., Williams, David R., Klein, Karl-Ludwig, Kontar, Eduard P., Smith, David M., Lagg, Andreas, Krucker, Sam, Hurford, Gordon J., Vilmer, Nicole, MacKinnon, Alexander L., Zharkova, Valentina V., Fletcher, Lyndsay, Hannah, Iain G., Browning, Philippa K., Innes, Davina E., Trottet, Gerard, Foullon, Clare, Nakariakov, Valery M., Green, Lucie M., Lamoureux, Herve, Forsyth, Colin, Walton, David M., Mathioudakis, Mihalis, Gandorfer, Achim, Martinez-Pillet, Valentin, Limousin, Olivier, Verwichte, Erwin, Dalla, Silvia, Mann, Gottfried, Aurass, Henri, and Neukirch, Thomas

Published
2012
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47. Understanding the plasma and magnetic field evolution of a filament using observations and non-linear force-free field modelling : evolution of an intermediate filament

Author

Yardley, Stephanie Louise, Savcheva, Antonia, Green, Lucie M., van Driel-Gesztelyi, Lidia, Long, David, Williams, David R., Mackay, Duncan Hendry, Science & Technology Facilities Council, and University of St Andrews. Applied Mathematics

Subjects
Astrophysics::High Energy Astrophysical Phenomena, 3rd-DAS, coronal mass ejections (CMEs) [Sun], evolution [Sun], QC Physics, magnetic fields [Sun], Physics::Space Physics, Sun, photosphere, Astrophysics::Solar and Stellar Astrophysics, filaments, prominences [Sun], QB Astronomy, activity [Sun], QC, QB
Abstract

Funding: UK STFC via PhD studentship and the Consolidated Grant SMC1/YST025 (S.L.Y.); STFC and Leverhulme trust (D.H.M.). We present observations and magnetic field models of an intermediate filament present on the Sun in August 2012, associated with a polarity inversion line that extends from AR 11541 in the east into the quiet sun at its western end. A combination of SDO/AIA, SDO/HMI, and GONG Hα data allow us to analyse the structure and evolution of the filament from 2012 August 4 23:00 UT to 2012 August 6 08:00 UT when the filament was in equilibrium. By applying the flux rope insertion method, nonlinear force-free field models of the filament are constructed using SDO/HMI line-of-sight magnetograms as the boundary condition at the two times given above. Guided by observed filament barbs, both modelled flux ropes are split into three sections each with a different value of axial flux to represent the non-uniform photospheric field distribution. The flux in the eastern section of the rope increases by 4x1020 Mx between the two models, which is in good agreement with the amount of flux cancelled along the internal PIL of AR 11541, calculated to be 3.2x1020 Mx. This suggests that flux cancellation builds flux into the filament's magnetic structure. Additionally, the number of field line dips increases between the two models in the locations where flux cancellation, the formation of new filament threads and growth of the filament is observed. This suggests that flux cancellation associated with magnetic reconnection forms concave-up magnetic field that lifts plasma into the filament. During this time, the free magnetic energy in the models increases by 0.2 x 1031 ergs. Postprint

Published
2019

48. Transient Inverse-FIP Plasma Composition Evolution within a Solar Flare

Author

Baker, Deborah, primary, Driel-Gesztelyi, Lidia van, additional, Brooks, David H., additional, Valori, Gherardo, additional, James, Alexander W., additional, Martin Laming, J., additional, Long, David M., additional, Démoulin, Pascal, additional, Green, Lucie M., additional, Matthews, Sarah A., additional, Oláh, Katalin, additional, and Kővári, Zsolt, additional

Published
2019
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49. The Magnetic Environment of a Stealth Coronal Mass Ejection.

Author

O'Kane, Jennifer, Cormack, Cecilia Mac, Mandrini, Cristina H., Démoulin, Pascal, Green, Lucie M., Long, David M., and Valori, Gherardo

Subjects
CORONAL mass ejections, MAGNETIC reconnection, SPACE environment, MAGNETIC fields, IMAGE processing
Abstract

Interest in stealth coronal mass ejections (CMEs) is increasing due to their relatively high occurrence rate and space weather impact. However, typical CME signatures such as extreme-ultraviolet dimmings and post-eruptive arcades are hard to identify and require extensive image processing techniques. These weak observational signatures mean that little is currently understood about the physics of these events. We present an extensive study of the magnetic field configuration in which the stealth CME of 2011 March 3 occurred. Three distinct episodes of flare ribbon formation are observed in the stealth CME source active region (AR). Two occurred prior to the eruption and suggest the occurrence of magnetic reconnection that builds the structure that will become eruptive. The third occurs in a time close to the eruption of a cavity that is observed in STEREO-B 171 Å data; this subsequently becomes part of the propagating CME observed in coronagraph data. We use both local (Cartesian) and global (spherical) models of the coronal magnetic field, which are complemented and verified by the observational analysis. We find evidence of a coronal null point, with field lines computed from its neighborhood connecting the stealth CME source region to two ARs in the northern hemisphere. We conclude that reconnection at the null point aids the eruption of the stealth CME by removing the field that acted to stabilize the preeruptive structure. This stealth CME, despite its weak signatures, has the main characteristics of other CMEs, and its eruption is driven by similar mechanisms. [ABSTRACT FROM AUTHOR]

Published
2021
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