Your search keyword '"Scolini, Camilla"' showing total 177 results

1. Employing the coupled EUHFORIA-OpenGGCM model to predict CME geoeffectiveness

Author

Maharana, Anwesha, Cramer, W. Douglas, Samara, Evangelia, Scolini, Camilla, Raeder, Joachim, and Poedts, Stefaan

Subjects

Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics

Abstract

EUropean Heliospheric FORecasting Information Asset (EUHFORIA) is a physics-based data-driven solar wind and CME propagation model designed for space weather forecasting and event analysis investigations. Although EUHFORIA can predict the solar wind plasma and magnetic field properties at Earth, it is not equipped to quantify the geoeffectiveness of the solar transients in terms of the geomagnetic indices like the disturbance storm time (Dst) index and the eauroral indices that quantify the impact of the magnetized plasma encounters on Earth's magnetosphere. Therefore, we couple EUHFORIA with the Open Geospace General Circulation Model (OpenGGCM), a magnetohydrodynamic model of the response of Earth's magnetosphere, ionosphere, and thermosphere, to transient solar wind characteristics. In this coupling, OpenGGCM is driven by the solar wind and interplanetary magnetic field obtained from EUHFORIA simulations to produce the magnetospheric and ionospheric response to the CMEs. This coupling is validated with two observed geoeffective CME events driven with the spheromak flux-rope CME model. We compare these simulation results with the indices obtained from OpenGGCM simulations driven by the measured solar wind data from spacecraft. We further employ the dynamic time warping (DTW) technique to assess the model performance in predicting Dst. The main highlight of this study is to use EUHFORIA simulated time series to predict the Dst and auroral indices 1 to 2 days in advance, as compared to using the observed solar wind data at L1, which only provides predictions 1 to 2 hours before the actual impact., Comment: Accepted in Space Weather on March 26, 2024

Published

2024

2. On the Origin of the sudden Heliospheric Open Magnetic Flux Enhancement during the 2014 Pole Reversal

Author

Heinemann, Stephan G., Owens, Mathew J., Temmer, Manuela, Turtle, James A., Arge, Charles N., Henney, Carl J., Pomoell, Jens, Asvestari, Eleanna, Linker, Jon A., Downs, Cooper, Caplan, Ronald M., Hofmeister, Stefan J., Scolini, Camilla, Pinto, Rui F., and Madjarska, Maria S.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Coronal holes are recognized as the primary sources of heliospheric open magnetic flux (OMF). However, a noticeable gap exists between in-situ measured OMF and that derived from remote sensing observations of the Sun. In this study, we investigate the OMF evolution and its connection to solar structures throughout 2014, with special emphasis on the period from September to October, where a sudden and significant OMF increase was reported. By deriving the OMF evolution at 1au, modeling it at the source surface, and analyzing solar photospheric data, we provide a comprehensive analysis of the observed phenomenon. First, we establish a strong correlation between the OMF increase and the solar magnetic field derived from a Potential Field Source Surface (PFSS) model ($cc_{\mathrm{Pearson}}=0.94$). Moreover, we find a good correlation between the OMF and the open flux derived from solar coronal holes ($cc_{\mathrm{Pearson}}=0.88$), although the coronal holes only contain $14-32\%$ of the Sun's total open flux. However, we note that while the OMF evolution correlates with coronal hole open flux, there is no correlation with the coronal hole area evolution ($cc_{\mathrm{Pearson}}=0.0$). The temporal increase in OMF correlates with the vanishing remnant magnetic field at the southern pole, caused by poleward flux circulations from the decay of numerous active regions months earlier. Additionally, our analysis suggests a potential link between the OMF enhancement and the concurrent emergence of the largest active region in solar cycle 24. In conclusion, our study provides insights into the strong increase in OMF observed during September to October 2014., Comment: accepted in ApJ

Published

2024

3. On the Role of Alfvenic Fluctuations as Mediators of Coherence within Interplanetary Coronal Mass Ejections: Investigation of Multi-Spacecraft Measurements at 1 au

Author

Scolini, Camilla, Lugaz, Noe, Winslow, Reka M., Farrugia, Charles J., Magyar, Norbert, and Bacchini, Fabio

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

Interplanetary coronal mass ejections (ICMEs) are defined as ''coherent'' if they are capable of responding to external perturbations in a collective manner. This implies that information must be able to propagate across ICME structures, and if this is not the case, single-point in-situ measurements cannot be considered as indicative of global ICME properties. Here, we investigate the role of Alfvenic fluctuations (AFs) as mediators of ICME coherence. We consider multi-point magnetic field and plasma measurements of 10 ICMEs observed by the ACE and Wind spacecraft at 1 au at longitudinal separations of 0.5{\deg}-0.7{\deg}. For each event, we analyze the Alfvenicity in terms of the residual energy and cross helicity of fluctuations, and the coherence in terms of the magnetic correlation between Wind and ACE. We find that ~65% and 90% of ICME sheaths and magnetic ejecta (MEs), respectively, present extended AFs covering at least 20% of the structure. Cross helicity suggests AFs of solar and interplanetary origin may co-exist in the ICME population at 1 au. AFs are mainly concentrated downstream of shocks and in the back of MEs. The magnetic field is poorly correlated within sheaths, while the correlation decreases from the front to the back of the MEs for most magnetic field components. AFs are also associated with lower magnetic field correlations. This suggests either that ICME coherence is not mediated by Alfven waves, implying that the coherence scale may be smaller than previously predicted, or that the magnetic field correlation is not a measure of coherence.

Published

2023

4. The Width of Magnetic Ejecta Measured Near 1 au: Lessons from STEREO-A Measurements in 2021--2022

Author

Lugaz, Noé, Zhuang, Bin, Scolini, Camilla, Al-Haddad, Nada, Farrugia, Charles J., Winslow, Réka M., Regnault, Florian, Möstl, Christian, Davies, Emma E., and Galvin, Antoinette B.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

Coronal mass ejections (CMEs) are large-scale eruptions with a typical radial size at 1 au of 0.21 au but their angular width in interplanetary space is still mostly unknown, especially for the magnetic ejecta (ME) part of the CME. We take advantage of STEREO-A angular separation of 20$^\circ$-60$^\circ$ from the Sun-Earth line from October 2020 to August 2022, and perform a two-part study to constrain the angular width of MEs in the ecliptic plane: a) we study all CMEs that are observed remotely to propagate between the Sun-STEREO-A and the Sun-Earth lines and determine how many impact one or both spacecraft in situ, and b) we investigate all in situ measurements at STEREO-A or at L1 of CMEs during the same time period to quantify how many are measured by the two spacecraft. A key finding is that, out of 21 CMEs propagating within 30$^\circ$ of either spacecraft, only four impacted both spacecraft and none provided clean magnetic cloud-like signatures at both spacecraft. Combining the two approaches, we conclude that the typical angular width of a ME at 1 au is $\sim$ 20$^\circ$-30$^\circ$, or 2-3 times less than often assumed and consistent with a 2:1 elliptical cross-section of an ellipsoidal ME. We discuss the consequences of this finding for future multi-spacecraft mission designs and for the coherence of CMEs., Comment: 21 pages, revision submitted to ApJ

Published

2023

5. Coronal Models and Detection of Open Magnetic Field

Author

Asvestari, Eleanna, Temmer, Manuela, Caplan, Ronald M., Linker, Jon A., Heinemann, Stephan G., Pinto, Rui F., Henney, Carl J., Arge, Charles N., Owens, Mathew J., Madjarska, Maria S., Pomoell, Jens, Hofmeister, Stefan J., Scolini, Camilla, and Samara, Evangelia

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

A plethora of coronal models, from empirical to more complex magnetohydrodynamic (MHD) ones, are being used for reconstructing the coronal magnetic field topology and estimating the open magnetic flux. However, no individual solution fully agrees with coronal hole observations and in situ measurements of open flux at 1~AU, as there is a strong deficit between model and observations contributing to the known problem of the missing open flux. In this paper we investigate the possible origin of the discrepancy between modeled and observed magnetic field topology by assessing the effect on the simulation output by the choice of the input boundary conditions and the simulation set up, including the choice of numerical schemes and the parameter initialization. In the frame of this work, we considered four potential field source surface based models and one fully MHD model, different types of global magnetic field maps and model initiation parameters. After assessing the model outputs using a variety of metrics, we conclude that they are highly comparable regardless of the differences set at initiation. When comparing all models to coronal hole boundaries extracted by extreme ultraviolet (EUV) filtergrams we find that they do not compare well. This miss-match between observed and modeled regions of open field is a candidate contributing to the open flux problem.

Published

2023

6. The effect of magnetic field line topology on ICME-related GCR modulation

Author

Davies, Emma E., Scolini, Camilla, Winslow, Réka M., Jordan, Andrew P., and Möstl, Christian

Subjects

Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics

Abstract

The large-scale magnetic structure of interplanetary coronal mass ejections (ICMEs) has been shown to affect the galactic cosmic ray (GCR) flux measured in situ by spacecraft, causing temporary decreases known as Forbush decreases (Fds). In some ICMEs, the magnetic ejecta exhibits a magnetic flux rope (FR) structure; the strong magnetic field strength and closed field line geometry of such ICME FRs has been proposed to act as a shield to GCR transport. In this study, we identify four ICMEs near Earth that drove Fds with similar mean magnetic field strengths (20 - 25 nT); two ICMEs with more typical mean speeds (~400 km/s), and two fast (~750 km/s) ICMEs. Within each speed pairing, we identify an ICME that exhibited an open magnetic field line topology and compare its effect on the GCR flux to that which exhibited a mostly closed topology. We investigate the different mechanisms that contribute to the resulting ICME-related Fds and their recovery, and determine which properties, if any, play a more important role than others in driving Fds. We find that much of the GCR response to the ICME events in this study is independent of the open or closed magnetic field line topology of the flux rope, and that features such as the fluctuations in speed, magnetic field structure, and expansion within the FR may play more of a role in determining the smaller-scale structure of the Fd profile.

Published

2023

7. Modeling a Coronal Mass Ejection from an Extended Filament Channel. II. Interplanetary Propagation to 1 au

Author

Palmerio, Erika, Maharana, Anwesha, Lynch, Benjamin J., Scolini, Camilla, Good, Simon W., Pomoell, Jens, Isavnin, Alexey, and Kilpua, Emilia K. J.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Earth and Planetary Astrophysics, Physics - Space Physics

Abstract

We present observations and modeling results of the propagation and impact at Earth of a high-latitude, extended filament channel eruption that commenced on 2015 July 9. The coronal mass ejection (CME) that resulted from the filament eruption was associated with a moderate disturbance at Earth. This event could be classified as a so-called "problem storm" because it lacked the usual solar signatures that are characteristic of large, energetic, Earth-directed CMEs that often result in significant geoeffective impacts. We use solar observations to constrain the initial parameters and therefore to model the propagation of the 2015 July 9 eruption from the solar corona up to Earth using 3D magnetohydrodynamic heliospheric simulations with three different configurations of the modeled CME. We find the best match between observed and modeled arrival at Earth for the simulation run that features a toroidal flux rope structure of the CME ejecta, but caution that different approaches may be more or less useful depending on the CME-observer geometry when evaluating the space weather impact of eruptions that are extreme in terms of their large size and high degree of asymmetry. We discuss our results in the context of both advancing our understanding of the physics of CME evolution and future improvements to space weather forecasting., Comment: 20 pages, 8 figures, 2 tables, accepted for publication in The Astrophysical Journal

Published

2023

8. New Observations Needed to Advance Our Understanding of Coronal Mass Ejections

Author

Palmerio, Erika, Lynch, Benjamin J., Lee, Christina O., Jian, Lan K., Nieves-Chinchilla, Teresa, Davies, Emma E., Wood, Brian E., Lugaz, Noé, Winslow, Réka M., Török, Tibor, Al-Haddad, Nada, Regnault, Florian, Jin, Meng, Scolini, Camilla, Carcaboso, Fernando, Farrugia, Charles J., Ledvina, Vincent E., Downs, Cooper, Kay, Christina, Pal, Sanchita, Salman, Tarik M., and Allen, Robert C.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

Coronal mass ejections (CMEs) are large eruptions from the Sun that propagate through the heliosphere after launch. Observational studies of these transient phenomena are usually based on 2D images of the Sun, corona, and heliosphere (remote-sensing data), as well as magnetic field, plasma, and particle samples along a 1D spacecraft trajectory (in-situ data). Given the large scales involved and the 3D nature of CMEs, such measurements are generally insufficient to build a comprehensive picture, especially in terms of local variations and overall geometry of the whole structure. This White Paper aims to address this issue by identifying the data sets and observational priorities that are needed to effectively advance our current understanding of the structure and evolution of CMEs, in both the remote-sensing and in-situ regimes. It also provides an outlook of possible missions and instruments that may yield significant improvements into the subject., Comment: White Paper submitted to the Heliophysics 2024-2033 Decadal Survey, 9 pages, 4 figures

Published

2023

9. The Need for Near-Earth Multi-Spacecraft Heliospheric Measurements and an Explorer Mission to Investigate Interplanetary Structures and Transients in the Near-Earth Heliosphere.

Author

Lugaz, Noé, Lee, Christina, Al-Haddad, Nada, Lillis, Robert, Jian, Lan, Curtis, David, Galvin, Antoinette, Whittlesey, Phyllis, Rahmati, Ali, Zesta, Eftyhia, Moldwin, Mark, Summerlin, Errol, Larson, Davin, Courtade, Sasha, French, Richard, Hunter, Richard, Covitti, Federico, Cosgrove, Daniel, Prall, J, Allen, Robert, Zhuang, Bin, Winslow, Réka, Scolini, Camilla, Lynch, Benjamin, Filwett, Rachael, Palmerio, Erika, Farrugia, Charles, Smith, Charles, Möstl, Christian, Weiler, Eva, Janvier, Miho, Regnault, Florian, Livi, Roberto, and Nieves-Chinchilla, Teresa

Subjects

Coronal mass ejection, Interplanetary space, Mission concept

Abstract

Based on decades of single-spacecraft measurements near 1 au as well as data from heliospheric and planetary missions, multi-spacecraft simultaneous measurements in the inner heliosphere on separations of 0.05-0.2 au are required to close existing gaps in our knowledge of solar wind structures, transients, and energetic particles, especially coronal mass ejections (CMEs), stream interaction regions (SIRs), high speed solar wind streams (HSS), and energetic storm particle (ESP) events. The Mission to Investigate Interplanetary Structures and Transients (MIIST) is a concept for a small multi-spacecraft mission to explore the near-Earth heliosphere on these critical scales. It is designed to advance two goals: (a) to determine the spatiotemporal variations and the variability of solar wind structures, transients, and energetic particle fluxes in near-Earth interplanetary (IP) space, and (b) to advance our fundamental knowledge necessary to improve space weather forecasting from in situ data. We present the scientific rationale for this proposed mission, the science requirements, payload, implementation, and concept of mission operation that address a key gap in our knowledge of IP structures and transients within the cost, launch, and schedule limitations of the NASA Heliophysics Small Explorers program.

Published

2024

10. Work-Life Balance Starts with Proper Deadlines and Exemplary Agencies

Author

Lugaz, Noé, Winslow, Réka M., Al-Haddad, Nada, Lee, Christina O., Vines, Sarah K., Reeves, Katharine, Caspi, Amir, Seaton, Daniel, Downs, Cooper, Glesener, Lindsay, Vourlidas, Angelos, Scolini, Camilla, Török, Tibor, Allen, Robert, and Palmerio, Erika

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Solar and Stellar Astrophysics, Physics - Physics and Society, Physics - Space Physics

Abstract

Diversity, equity and inclusion (DEI) programs can only be implemented successfully if proper work-life balance is possible in Heliophysics (and in STEM field in general). One of the core issues stems from the culture of "work-above-life" associated with mission concepts, development, and implementation but also the expectations that seem to originate from numerous announcements from NASA (and other agencies). The benefits of work-life balance are well documented; however, the entire system surrounding research in Heliophysics hinders or discourages proper work-life balance. For example, there does not seem to be attention paid by NASA Headquarters (HQ) on the timing of their announcements regarding how it will be perceived by researchers, and how the timing may promote a culture where work trumps personal life. The same is true for remarks by NASA HQ program officers during panels or informal discussions, where seemingly innocuous comments may give a perception that work is expected after "normal" work hours. In addition, we are calling for work-life balance plans and implementation to be one of the criteria used for down-selection and confirmation of missions (Key Decision Points: KDP-B, KDP-C)., Comment: White paper submitted to the Decadal Survey for Solar and Space Physics (Heliophysics) 2024-2033; 6 pages

Published

2023

11. Evolution of the Radial Size and Expansion of Coronal Mass Ejections Investigated by Combining Remote and In-Situ Observations

Author

Zhuang, Bin, Lugaz, Noé, Al-Haddad, Nada, Winslow, Réka M., Scolini, Camilla, Farrugia, Charles J., and Galvin, Antoinette B.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

A fundamental property of coronal mass ejections (CMEs) is their radial expansion, which determines the increase in the CME radial size and the decrease in the CME magnetic field strength as the CME propagates. CME radial expansion can be investigated either by using remote observations or by in-situ measurements based on multiple spacecraft in radial conjunction. However, there have been only few case studies combining both remote and in-situ observations. It is therefore unknown if the radial expansion estimated remotely in the corona is consistent with that estimated locally in the heliosphere. To address this question, we first select 22 CME events between the years 2010 and 2013, which were well observed by coronagraphs and by two or three spacecraft in radial conjunction. We use the graduated cylindrical shell model to estimate the radial size, radial expansion speed, and a measure of the dimensionless expansion parameter of CMEs in the corona. The same parameters and two additional measures of the radial-size increase and magnetic-field-strength decrease with heliocentric distance of CMEs based on in-situ measurements are also calculated. For most of the events, the CME radial size estimated by remote observations is inconsistent with the in-situ estimates. We further statistically analyze the correlations of these expansion parameters estimated using remote and in-situ observations, and discuss the potential reasons for the inconsistencies and their implications for the CME space weather forecasting., Comment: Accepted by ApJ

Published

2023

12. Rotation and interaction of the September 8 and 10, 2014 CMEs tested with EUHFORIA

Author

Maharana, Anwesha, Scolini, Camilla, Schmieder, Brigitte, and Poedts, Stefaan

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Solar coronal mass ejections (CMEs) can catch up and interact with preceding CMEs and solar wind structures to undergo rotation and deflection during their propagation. We aim to show how interactions undergone by a CME in the corona and heliosphere can play a significant role in altering its geoeffectiveness predicted at the time of its eruption. We consider a case study of two successive CMEs launched from the active region NOAA 12158 in early September 2014. The second CME was predicted to be extensively geoeffective based on the remote-sensing observations of the source region. However, in situ measurements at 1~au recorded only a short-lasting weak negative Bz component followed by a prolonged positive Bz component. The EUropean Heliosphere FORecasting Information Asset (EUHFORIA) is used to perform a self-consistent 3D MHD simulation of the two CMEs in the heliosphere. The initial conditions of the CMEs are determined by combining observational insights near the Sun, fine-tuned to match the in situ observations near 1~au, and additional numerical experiments of each individual CME. By introducing CME1 before CME2 in the EUHFORIA simulation, we modelled the negative Bz component in the sheath region ahead of CME2 whose formation can be attributed to the interaction between CME1 and CME2. To reproduce the positive Bz component in the magnetic ejecta of CME2, we had to initialise CME2 with an orientation determined at 0.1~au and consistent with the orientation interpreted at 1~au, instead of the orientation observed during its eruption. EUHFORIA simulations suggest the possibility of a significant rotation of CME2 in the low corona in order to explain the in situ observations at 1~au. Coherent magnetic field rotations, potentially geoeffective, can be formed in the sheath region as a result of CME-CME interactions in the heliosphere even if the individual CMEs are not geoeffective., Comment: The paper is accepted in A&A journal for publication on May 5, 2023

Published

2023

13. Quantifying errors in 3D CME parameters derived from synthetic data using white-light reconstruction techniques

Author

Verbeke, Christine, Mays, M. Leila, Kay, Christina, Riley, Pete, Palmerio, Erika, Dumbović, Mateja, Mierla, Marilena, Scolini, Camilla, Temmer, Manuela, Paouris, Evangelos, Balmaceda, Laura A., Cremades, Hebe, and Hinterreiter, Jürgen

Subjects

Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

(Shortened version) Current efforts in space weather forecasting of CMEs have been focused on predicting their arrival time and magnetic structure. To make predictions, methods have been developed to derive the true CME speed, size and position, among others. Difficulties in determining input parameters for CME forecasting arise from the lack of direct measurements of the coronal magnetic fields and uncertainties in estimating the CME 3D geometric and kinematic parameters. White-light coronagraph images are usually employed by a variety of CME reconstruction techniques. We explore how subjectivity affects the 3D CME parameters that are obtained from the GCS reconstruction technique. We have designed two different synthetic scenarios where the ``true'' geometric parameters are known in order to quantify such uncertainties for the first time. We explore this as follows: 1) Using the ray-tracing option from the GCS model software, and 2) Using 3D MHD simulation data from the MAS code. Our experiment includes different viewing configurations using single and multiple viewpoints. CME reconstructions using a single viewpoint had the largest errors and error ranges for both synthetic GCS and simulated MHD white-light data. Increasing the number of viewpoints to two, the errors decreased by about 4$^\circ$ in latitude, 22$^\circ$ in longitude, 14$^\circ$ in tilt, and 10$^\circ$ in half-angle, pointing towards a need for at least two viewpoints. We found the following CME parameter error bars as a starting point for quantifying the minimum error in CME parameters from white-light reconstructions: $\Delta\theta$ (latitude)=${6^\circ}$, $\Delta\phi$ (longitude)=${11^\circ}$, $\Delta\gamma$ (tilt)=${25^\circ}$, $\Delta\alpha$ (half-angle)=${10^\circ}$, $\Delta h$ (height)=$0.6 R_{\odot}$, and $\Delta\kappa$ (ratio)=$0.1$.

Published

2023

14. Characteristic Scales of Complexity and Coherence within Interplanetary Coronal Mass Ejections: Insights from Spacecraft Swarms in Global Heliospheric Simulations

Author

Scolini, Camilla, Winslow, Reka M., Lugaz, Noé, and Poedts, Stefaan

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

Many aspects of the three-dimensional (3-D) structure and evolution of interplanetary coronal mass ejections (ICMEs) remain unexplained. Here, we investigate two main topics: (1) the coherence scale of magnetic fields inside ICMEs, and (2) the dynamic nature of ICME magnetic complexity. We simulate ICMEs interacting with different solar winds using the linear force-free spheromak model incorporated into the EUHFORIA model. We place a swarm of ~20000 spacecraft in the 3-D simulation domain and characterize ICME magnetic complexity and coherence at each spacecraft based on simulated time series. Our simulations suggest that ICMEs retain a lower complexity and higher coherence along their magnetic axis, but that a characterization of their global complexity requires crossings along both the axial and perpendicular directions. For an ICME of initial half angular width of $45^\circ$ that does not interact with other large-scale solar wind structures, global complexity can be characterized by as little as 7-12 spacecraft separated by $25^\circ$, but the minimum number of spacecraft rises to 50-65 (separated by $10^\circ$) if interactions occur. Without interactions, ICME coherence extends for $45^\circ$, $20^\circ$-$30^\circ$, $15^\circ$-$30^\circ$, and $0^\circ$-$10^\circ$ for $B$, $B_\phi$, $B_\theta$, and $B_r$, respectively. Coherence is also lower in the ICME west flank compared to the east flank due to Parker spiral effects. Moreover, coherence is reduced by a factor of 3-6 by interactions with solar wind structures. Our findings help constrain some of the critical scales that control the evolution of ICMEs and aid in the planning of future dedicated multi-spacecraft missions.

Published

2022

15. Implementation and validation of the FRi3D flux rope model in EUHFORIA

Author

Maharana, Anwesha, Isavnin, Alexey, Scolini, Camilla, Wijsen, Nicolas, Rodriguez, Luciano, Mierla, Marilena, Magdalenic, Jasmina, and Poedts, Stefaan

Subjects

Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Earth and Planetary Astrophysics, Physics - Space Physics

Abstract

The Flux Rope in 3D (FRi3D, Isavnin, 2016), a coronal mass ejection (CME) model with global three-dimensional (3D) geometry, has been implemented in the space weather forecasting tool EUHFORIA (Pomoell and Poedts, 2018). By incorporating this advanced flux rope model in EUHFORIA, we aim to improve the modelling of CME flank encounters and, most importantly, the magnetic field predictions at Earth. After using synthetic events to showcase FRi3D's capabilities of modelling CME flanks, we optimize the model to run robust simulations of real events and test its predictive capabilities. We perform observation-based modelling of the halo CME event that erupted on 12 July 2012. The geometrical input parameters are constrained using the forward modelling tool included in FRi3D with additional flux rope geometry flexibilities as compared to the pre-existing models. The magnetic field input parameters are derived using the differential evolution algorithm to fit FRi3D parameters to the in situ data at 1 AU. An observation-based approach to constrain the density of CMEs is adopted, in order to achieve a better estimation of mass corresponding to the FRi3D geometry. The CME is evolved in EUHFORIA's heliospheric domain and a comparison of FRi3D's predictive performance with the previously implemented spheromak CME in EUHFORIA is presented. For this event, FRi3D improves the modelling of the total magnetic field magnitude and Bz at Earth by ~30% and ~70%, respectively. Moreover, we compute the expected geoeffectiveness of the storm at Earth using an empirical Dst model and find that the FRi3D model improves the predictions of minimum Dst by ~20% as compared to the spheromak CME model. Finally, we discuss the limitations of the current implementation of FRi3D in EUHFORIA and propose possible improvements., Comment: 22 pages, 14 figures

Published

2022

16. Multi-Spacecraft Observations of the Evolution of Interplanetary Coronal Mass Ejections Between 0.3 and 2.2 AU: Conjunctions with the Juno Spacecraft

Author

Davies, Emma E., Winslow, Réka M., Scolini, Camilla, Forsyth, Robert J., Möstl, Christian, Lugaz, Noé, and Galvin, Antoinette B.

Subjects

Physics - Space Physics

Abstract

We present a catalogue of 35 interplanetary coronal mass ejections (ICMEs) observed by the Juno spacecraft and at least one other spacecraft during its cruise phase to Jupiter. We identify events observed by MESSENGER, Venus Express, Wind, and STEREO with magnetic features that can be matched unambiguously with those observed by Juno. A multi-spacecraft study of ICME properties between 0.3 and 2.2 AU is conducted: we firstly investigate the global expansion by tracking the variation in magnetic field strength with increasing heliocentric distance of individual ICME events, finding significant variability in magnetic field relationships for individual events in comparison with statistical trends. With the availability of plasma data at 1 AU, the local expansion at 1 AU can be compared with global expansion rates between 1 AU and Juno. Despite following expected trends, the local and global expansion rates are only weakly correlated. Finally, for those events with clearly identifiable magnetic flux ropes, we investigate the orientation of the flux rope axis as they propagate; we find that 64% of events displayed a decrease in inclination with increasing heliocentric distance, and 40% of events undergo a significant change in orientation as they propagate towards Juno. The multi-spacecraft catalogue produced in this study provides a valuable link between ICME observations in the inner heliosphere and beyond 1 AU, thereby improving our understanding of ICME evolution.

Published

2022

17. A Coronal Mass Ejection and Magnetic Ejecta Observed In Situ by STEREO-A and Wind at 55$^\circ$ Angular Separation

Author

Lugaz, Noé, Salman, Tarik M., Farrugia, Charles J., Yu, Wenyuan, Zhuang, Bin, Al-Haddad, Nada, Scolini, Camilla, Winslow, Réka M., Möstl, Christian, Davies, Emma E., and Galvin, Antoinette B.

Subjects

Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics

Abstract

We present an analysis of {\it in situ} and remote-sensing measurements of a coronal mass ejection (CME) that erupted on 2021 February 20 and impacted both the Solar TErrestrial RElations Observatory (STEREO)-A and the {\it Wind} spacecraft, which were separated longitudinally by 55$^\circ$. Measurements on 2021 February 24 at both spacecraft are consistent with the passage of a magnetic ejecta (ME), making this one of the widest reported multi-spacecraft ME detections. The CME is associated with a low-inclined and wide filament eruption from the Sun's southern hemisphere, which propagates between STEREO-A and {\it Wind} around E34. At STEREO-A, the measurements indicate the passage of a moderately fast ($\sim 425$~km\,s$^{-1}$) shock-driving ME, occurring 2--3 days after the end of a high speed stream (HSS). At {\it Wind}, the measurements show a faster ($\sim 490$~km\,s$^{-1}$) and much shorter ME, not preceded by a shock nor a sheath, and occurring inside the back portion of the HSS. The ME orientation measured at both spacecraft is consistent with a passage close to the legs of a curved flux rope. The short duration of the ME observed at {\it Wind} and the difference in the suprathermal electron pitch-angle data between the two spacecraft are the only results that do not satisfy common expectations. We discuss the consequence of these measurements on our understanding of the CME shape and extent and the lack of clear signatures of the interaction between the CME and the HSS., Comment: accepted to ApJ

Published

2022

18. Observation-based modelling of the energetic storm particle event of 14 July 2012

Author

Wijsen, Nicolas, Aran, Angels, Scolini, Camilla, Lario, David, Afanasiev, Alexandr, Vainio, Rami, Sanahuja, Blai, Pomoell, Jens, and Poedts, Stefaan

Subjects

Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics

Abstract

We model the energetic storm particle (ESP) event of 14 July 2012 using the energetic particle acceleration and transport model named PARADISE, together with the solar wind and coronal mass ejection (CME) model named EUHFORIA. The simulation results illustrate both the capabilities and limitations of the utilised models. We show that the models capture some essential structural features of the ESP event; however, for some aspects the simulations and observations diverge. We describe and, to some extent, assess the sources of errors in the modelling chain of EUHFORIA and PARADISE and discuss how they may be mitigated in the future. The PARADISE model evolves energetic particle distributions in a background solar wind generated by the ideal MHD module of EUHFORIA. The CME generating the ESP event is simulated by using the spheromak model of EUHFORIA, which approximates the CME's flux rope as a linear force-free spheroidal magnetic field. In addition, a tool was developed to trace CME-driven shock waves in the EUHFORIA simulation domain. This tool is used in PARADISE to (i) inject 50 keV protons continuously at the CME-driven shock and (ii) include a foreshock and a sheath region, in which the energetic particle parallel mean free path, $\lambda_\parallel$, decreases towards the shock wave. The value of $\lambda_\parallel$ at the shock wave is estimated from in situ observations of the ESP event. For energies below 1 MeV, the simulation results agree well with both the upstream and downstream components of the ESP event observed by the Advanced Composition Explorer (ACE). This suggests that these low-energy protons are mainly the result of interplanetary particle acceleration. In the downstream region, the sharp drop in the energetic particle intensities is reproduced at the entry into the following magnetic cloud, illustrating the importance of a magnetised CME model., Comment: 14 pages, 10 figures, accepted for publication in Astronomy & Astrophysics

Published

2022

19. Causes and Consequences of Magnetic Complexity Changes within Interplanetary Coronal Mass Ejections: a Statistical Study

Author

Scolini, Camilla, Winslow, Réka M., Lugaz, Noé, Salman, Tarik M., Davies, Emma E., and Galvin, Antoinette B.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

We present the first statistical analysis of complexity changes affecting the magnetic structure of interplanetary coronal mass ejections (ICMEs), with the aim of answering the questions: How frequently do ICMEs undergo magnetic complexity changes during propagation? What are the causes of such changes? Do the in situ properties of ICMEs differ depending on whether they exhibit complexity changes? We consider multi-spacecraft observations of 31 ICMEs by MESSENGER, Venus Express, ACE, and STEREO between 2008 and 2014 while radially aligned. By analyzing their magnetic properties at the inner and outer spacecraft, we identify complexity changes which manifest as fundamental alterations or significant re-orientations of the ICME. Plasma and suprathermal electron data at 1 au, and simulations of the solar wind enable us to reconstruct the propagation scenario for each event, and to identify critical factors controlling their evolution. Results show that ~65% of ICMEs change their complexity between Mercury and 1 au and that interaction with multiple large-scale solar wind structures is the driver of these changes. Furthermore, 71% of ICMEs observed at large radial (>0.4 au) but small longitudinal (<15 degrees) separations exhibit complexity changes, indicating that propagation over large distances strongly affects ICMEs. Results also suggest ICMEs may be magnetically coherent over angular scales of at least 15 degrees, supporting earlier theoretical and observational estimates. This work presents statistical evidence that magnetic complexity changes are consequences of ICME interactions with large-scale solar wind structures, rather than intrinsic to ICME evolution, and that such changes are only partly identifiable from in situ measurements at 1 au.

Published

2021

20. Evolution of interplanetary coronal mass ejection complexity: a numerical study through a swarm of simulated spacecraft

Author

Scolini, Camilla, Winslow, Reka M., Lugaz, Noé, and Poedts, Stefaan

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

In-situ measurements carried out by spacecraft in radial alignment are critical to advance our knowledge on the evolutionary behavior of coronal mass ejections (CMEs) and their magnetic structures during propagation through interplanetary space. Yet, the scarcity of radially aligned CME crossings restricts investigations on the evolution of CME magnetic structures to a few case studies, preventing a comprehensive understanding of CME complexity changes during propagation. In this paper, we perform numerical simulations of CMEs interacting with different solar wind streams using the linear force-free spheromak CME model incorporated into the EUropean Heliospheric FORecasting Information Asset (EUHFORIA) model. The novelty of our approach lies in the investigation of the evolution of CME complexity using a swarm of radially aligned, simulated spacecraft. Our scope is to determine under which conditions, and to what extent, CMEs exhibit variations of their magnetic structure and complexity during propagation, as measured by spacecraft that are radially aligned. Results indicate that the interaction with large-scale solar wind structures, and particularly with stream interaction regions, doubles the probability to detect an increase of the CME magnetic complexity between two spacecraft in radial alignment, compared to cases without such interactions. This work represents the first attempt to quantify the probability of detecting complexity changes in CME magnetic structures by spacecraft in radial alignment using numerical simulations, and it provides support to the interpretation of multi-point CME observations involving past, current (such as Parker Solar Probe and Solar Orbiter), and future missions.

Published

2021

21. First simultaneous in situ measurements of a coronal mass ejection by Parker Solar Probe and STEREO-A

Author

Winslow, Reka M., Lugaz, Noé, Scolini, Camilla, and Galvin, Antoinette B.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

We present the first PSP-observed CME that hits a second spacecraft before the end of the PSP encounter, providing an excellent opportunity to study short-term CME evolution. The CME was launched from the Sun on 10 October 2019 and was measured in situ at PSP on 13 October 2019 and at STEREO-A on 14 October 2019. The small, but not insignificant, radial (~0.15 au) and longitudinal (~8 deg) separation between PSP and STEREO-A at this time allows for observations of both short-term radial evolution as well as investigation of the global CME structure in longitude. Although initially a slow CME, magnetic field and plasma observations indicate that the CME drove a shock at STEREO-A and also exhibited an increasing speed profile through the CME (i.e. evidence for compression). We find that the presence of the shock and other compression signatures at 1 au are due to the CME having been overtaken and accelerated by a high speed solar wind stream (HSS). We estimate the minimum interaction time between the CME and the HSS to be about 2.5 days, indicating the interaction started well before the CME arrival at PSP and STEREO-A. Despite alterations of the CME by the HSS, we find that the CME magnetic field structure is similar between the vantage points, with overall the same flux rope classification and the same field distortions present. These observations are consistent with the fact that coherence in the magnetic structure is needed for steady and continued acceleration of the CME.

Published

2021

22. The effect of stream interaction regions on ICME structures observed in longitudinal conjunction

Author

Winslow, Reka M., Scolini, Camilla, Lugaz, Noé, and Galvin, Antoinette B.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

We study two interplanetary coronal mass ejections (ICMEs) observed at Mercury and 1 AU by spacecraft in longitudinal conjunction, investigating the question: what causes the drastic alterations observed in some ICMEs during propagation, while other ICMEs remain relatively unchanged? Of the two ICMEs, the first one propagated relatively self-similarly, while the second one underwent significant changes in its properties. We focus on the presence or absence of large-scale corotating structures in the ICME propagation space between Mercury and 1 AU, that have been shown to influence the orientation of ICME magnetic structures and the properties of ICME sheaths. We determine the flux rope orientation at the two locations using force-free flux rope fits as well as the classification by Nieves-Chinchilla et al. (2019). We also use measurements of plasma properties at 1 AU, the size evolution of the sheaths and ME with heliocentric distance, and identification of structures in the propagation space based on in situ data, remote-sensing observations, and simulations of the steady-state solar wind, to complement our analysis. Results indicate that the changes observed in one ICME were likely caused by a stream interaction region, while the ICME exhibiting little change did not interact with any transients between Mercury and 1 AU. This work provides an example of how interactions with corotating structures in the solar wind can induce fundamental changes in ICMEs. Our findings can help lay the foundation for improved predictions of ICME properties at 1 AU.

Published

2021

23. Exploring the radial evolution of Interplanetary Coronal Mass Ejections using EUHFORIA

Author

Scolini, Camilla, Dasso, Sergio, Rodriguez, Luciano, Zhukov, Andrei N., and Poedts, Stefaan

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

Coronal Mass Ejections (CMEs) are large-scale eruptions from the Sun into interplanetary space. Despite being major space weather drivers, our knowledge of the CME properties in the inner heliosphere remains constrained by the scarcity of observations at distances other than 1 au. Furthermore, most CMEs are observed in situ by single spacecraft, requiring numerical models to complement the sparse observations available. We aim to assess the ability of the linear force-free spheromak CME model in EUHFORIA to describe the radial evolution of interplanetary CMEs, yielding new context for observational studies. We model one well-studied CME, and investigate its radial evolution by placing virtual spacecraft along the Sun-Earth line in the simulation domain. To directly compare observational and modelling results, we characterise the interplanetary CME signatures between 0.2 and 1.9 au from modelled time series, exploiting techniques traditionally employed to analyse real in situ data. Results show that the modelled radial evolution of the mean solar wind and CME values is consistent with observational and theoretical expectations. The CME expands as a consequence of the decaying pressure in the surrounding wind: the expansion is rapid within 0.4 au, and moderate at larger distances. The early rapid expansion could not explain the overestimated CME radial size in our simulation, suggesting this is an intrinsic limitation of the spheromak geometry used. The magnetic field profile indicates a relaxation of the CME during propagation, while ageing is most probably not a substantial source of magnetic asymmetry beyond 0.4 au. We also report a CME wake that is significantly shorter than suggested by observations. Overall, EUHFORIA provides a consistent description of the radial evolution of solar wind and CMEs; nevertheless, improvements are required to better reproduce the CME radial extension.

Published

2021

24. Implementing the MULTI-VP coronal model in EUHFORIA: test case results and comparisons with the WSA coronal model

Author

Samara, Evangelia, Pinto, Rui F., Magdalenic, Jasmina, Wijsen, Nicolas, Jercic, Veronika, Scolini, Camilla, Jebaraj, Immanuel C., Rodriguez, Luciano, and Poedts, Stefaan

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

In this study, we focus on improving EUHFORIA (European Heliospheric Forecasting Information Asset), a recently developed 3D MHD space weather prediction tool. EUHFORIA consists of two parts, covering two spatial domains; the solar corona and the inner heliosphere. For the first part, the semi-empirical Wang-Sheeley-Arge (WSA) model is used by default, which employs the Potential Field Source Surface (PFSS) and Schatten Current Sheet (SCS) models to provide the necessary solar wind plasma and magnetic conditions above the solar surface, at 0.1 AU, that serve as boundary conditions for the inner heliospheric part. Herein, we present the first results of the implementation of an alternative coronal model in EUHFORIA, the so-called MULTI-VP model. We compared the output of the default coronal model with the output from MULTI-VP at the inner boundary of the heliospheric domain of EUHFORIA in order to understand differences between the two models, before they propagate to Earth. We also compared the performance of WSA+EUHFORIA-heliosphere and MULTI-VP+EUHFORIA-heliosphere against in situ observations at Earth. In the frame of this study, we considered two different high-speed stream cases, one during a period of low solar activity and one during a period of high solar activity. We also employed two different magnetograms, i.e., GONG and WSO. Our results show that the choice of both the coronal model and the magnetogram play an important role on the accuracy of the solar wind prediction. However, it is not clear which component plays the most important role for the modeled results obtained at Earth. A statistical analysis with an appropriate number of simulations is needed to confirm our findings., Comment: Accepted for publication in Astronomy and Astrophysics

Published

2021

25. Using radio triangulation to understand the origin of two subsequent type II radio bursts

Author

Jebaraj, Immanuel Christopher, Magdalenic, Jasmina, Podladchikova, Tatiana, Scolini, Camilla, Pomoell, Jens, Veronig, Astrid, Dissauer, Karin, Krupar, Vratislav, Kilpua, Emilia, and Poedts, Stefaan

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Context: Eruptive events such as coronal mass ejections (CMEs) and flares accelerate particles and generate shock waves which can arrive at Earth and can disturb the magnetosphere. Understanding the association between CMEs and CME-driven shocks is therefore highly important for space weather studies. Aims: We present a study of the CME/flare event associated with two type II bursts observed on September 27, 2012. The aim of the study is to understand the relationship between the observed CME and the two distinct shock wave signatures. Methods: The multi-wavelength study of the eruptive event (CME/flare) was complemented with radio triangulation of the associated radio emission and modelling of the CME and the shock wave employing MHD simulations. Results: We found that, although temporal association between the type II bursts and the CME is good, the low-frequency type II(LF-type II) burst occurs significantly higher in the corona than the CME and its relationship to the CME is not straightforward. The analysis of the EIT wave (coronal bright front) shows the fastest wave component to be in the southeast quadrant of the Sun. This is also the quadrant in which the source positions of the LF-type II were found to be located, probably resulting from the interaction between the shock wave and a streamer. Conclusions: The relationship between the CME/flare event and the shock wave signatures is discussed using the temporal association,as well as the spatial information of the radio emission. Further, we discuss the importance and possible effects of the frequently non-radial propagation of the shock wave., Comment: 16 pages, 14 figures, accepted for publication in Astronomy and Astrophysics

Published

2020

26. CME-CME Interactions as Sources of CME Geo-effectiveness: The Formation of the Complex Ejecta and Intense Geomagnetic Storm in Early September 2017

Author

Scolini, Camilla, Chané, Emmanuel, Temmer, Manuela, Kilpua, Emilia K. J., Dissauer, Karin, Veronig, Astrid M., Palmerio, Erika, Pomoell, Jens, Dumbović, Mateja, Guo, Jingnan, Rodriguez, Luciano, and Poedts, Stefaan

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

Coronal mass ejections (CMEs) are the primary sources of intense disturbances at Earth, where their geo-effectiveness is largely determined by their dynamic pressure and internal magnetic field, which can be significantly altered during interactions with other CMEs in interplanetary space. We analyse three successive CMEs that erupted from the Sun during September 4-6, 2017, investigating the role of CME-CME interactions as source of the associated intense geomagnetic storm (Dst_min=-142 nT on September 7). To quantify the impact of interactions on the (geo-)effectiveness of individual CMEs, we perform global heliospheric simulations with the EUHFORIA model, using observation-based initial parameters with the additional purpose of validating the predictive capabilities of the model for complex CME events. The simulations show that around 0.45 AU, the shock driven by the September 6 CME started compressing a preceding magnetic ejecta formed by the merging of two CMEs launched on September 4, significantly amplifying its Bz until a maximum factor of 2.8 around 0.9 AU. The following gradual conversion of magnetic energy into kinetic and thermal components reduced the Bz amplification until its almost complete disappearance around 1.8 AU. We conclude that a key factor at the origin of the intense storm triggered by the September 4-6, 2017 CMEs was their arrival at Earth during the phase of maximum Bz amplification. Our analysis highlights how the amplification of the magnetic field of individual CMEs in space-time due to interaction processes can be characterised by a growth, a maximum, and a decay phase, suggesting that the time interval between the CME eruptions and their relative speeds are critical factors in determining the resulting impact of complex CMEs at various heliocentric distances (helio-effectiveness).

Published

2019

27. Multipoint study of successive coronal mass ejections driving moderate disturbances at 1 AU

Author

Palmerio, Erika, Scolini, Camilla, Barnes, David, Magdalenić, Jasmina, West, Matthew J., Zhukov, Andrei N., Rodriguez, Luciano, Mierla, Marilena, Good, Simon W., Morosan, Diana E., Kilpua, Emilia K. J., Pomoell, Jens, and Poedts, Stefaan

Subjects

Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Earth and Planetary Astrophysics, Physics - Space Physics

Abstract

We analyse in this work the propagation and geoeffectiveness of four successive coronal mass ejections (CMEs) that erupted from the Sun during 21--23 May 2013 and that were detected in interplanetary space by the Wind and/or STEREO-A spacecraft. All these CMEs featured critical aspects for understanding so-called "problem space weather storms" at Earth. In the first three events a limb CMEs resulted in moderately geoeffective in-situ structures at their target location in terms of the disturbance storm time (Dst) index (either measured or estimated). The fourth CME, which also caused a moderate geomagnetic response, erupted from close to the disc centre as seen from Earth, but it was not visible in coronagraph images from the spacecraft along the Sun--Earth line and appeared narrow and faint from off-angle viewpoints. Making the correct connection between CMEs at the Sun and their in-situ counterparts is often difficult for problem storms. We investigate these four CMEs using multiwavelength and multipoint remote-sensing observations (extreme ultraviolet, white light, and radio), aided by 3D heliospheric modelling, in order to follow their propagation in the corona and in interplanetary space and to assess their impact at 1 AU. Finally, we emphasise the difficulties in forecasting moderate space weather effects provoked by problematic and ambiguous events and the importance of multispacecraft data for observing and modelling problem storms., Comment: 20 pages, 10 figures, 3 tables, accepted for publication in The Astrophysical Journal

Published

2019

28. Observation-based modelling of magnetised Coronal Mass Ejections with EUHFORIA

Author

Scolini, Camilla, Rodriguez, Luciano, Mierla, Marilena, Pomoell, Jens, and Poedts, Stefaan

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Coronal Mass Ejections (CMEs) are the primary source of strong space weather disturbances at Earth. Their geoeffectiveness is largely determined by their dynamic pressure and internal magnetic fields, for which reliable predictions at Earth are not possible with traditional cone CME models. We study two Earth-directed CMEs using the EUropean Heliospheric FORecasting Information Asset (EUHFORIA) model, testing the predictive capabilities of a linear force-free spheromak CME model initialised using parameters derived from remote-sensing observations. Using observation-based CME input parameters, we perform MHD simulations of the events with the cone and spheromak CME models. Results show that spheromak CMEs propagate faster than cone CMEs when initialised with the same kinematic parameters. We interpret these differences as due to different Lorentz forces acting within cone and spheromak CMEs, leading to different CME expansions. Such discrepancies can be mitigated by initialising spheromak CMEs with a reduced speed corresponding to the radial speed only. Results at Earth evidence that the spheromak model improves the predictions of B(Bz) up to 12-60(22-40) percentage points compared to a cone model. Considering virtual spacecraft located around Earth, B(Bz) predictions reach 45-70%(58-78%) of the observed peak values. The spheromak model predicts inaccurate magnetic field parameters at Earth for CMEs propagating away from the Sun-Earth line, while it successfully predicts the CME properties and arrival time in the case of strictly Earth-directed events. Modelling CMEs propagating away from the Sun-Earth line requires extra care due to limitations related to the assumed spherical shape. The spatial variability of modelling results and the typical uncertainties in the reconstructed CME direction advocate the need to consider predictions at Earth and at virtual spacecraft around it.

Published

2019

29. CME propagation through the heliosphere: Status and future of observations and model development

Author

Temmer, Manuela, Scolini, Camilla, Richardson, Ian G., Heinemann, Stephan G., Paouris, Evangelos, Vourlidas, Angelos, Bisi, Mario M., Al-Haddad, N., Amerstorfer, T., Barnard, L., Burešová, D., Hofmeister, S.J., Iwai, K., Jackson, B.V., Jarolim, R., Jian, L.K., Linker, J.A., Lugaz, N., Manoharan, P.K., Mays, M.L., Mishra, W., Owens, M.J., Palmerio, E., Perri, B., Pomoell, J., Pinto, R.F., Samara, E., Singh, T., Sur, D., Verbeke, C., Veronig, A.M., and Zhuang, B.

Published

2023

30. The spheroid CME model in EUHFORIA

Author

Scolini Camilla and Palmerio Erika

Subjects

coronal mass ejections, space weather predictions, magnetohydrodynamics, Meteorology. Climatology, QC851-999

Abstract

Predictions of coronal mass ejection (CME) propagation and impact in the heliosphere, in either research or operational settings, are usually performed by employing magnetohydrodynamic (MHD) models. Within such simulations, the CME ejecta is often described as a hydrodynamic pulse that lacks an internal magnetic field and is characterized by a spherical geometry – leading to the so-called cone CME model. White-light observations of CMEs in the corona, however, reveal that the morphology of these structures resembles more closely that of a croissant, i.e., exhibiting an elongated cross-section of their front. It follows that, in space weather forecasts, the assumption of a spherical geometry may result in erroneous predictions of CME impacts in the heliosphere in terms of hit/miss and arrival time/speed, especially in the case of flank encounters. A spheroid CME model is expected to provide a more accurate description of the elongated morphology that is often observed in CMEs. In this paper, we describe the implementation and initial validation of the spheroid CME model within the MHD EUropean Heliospheric FORecasting Information Asset (EUHFORIA) code. We perform EUHFORIA simulations of an idealized CME as well as a “real” event to compare the spheroidal model with the traditional cone one. We show how the initial ejecta geometry can lead to substantially different estimates in terms of CME impact, arrival time/speed, and geoeffectiveness, especially with increasing distance to the CME nose.

Published

2024

31. Halo Coronal Mass Ejections during Solar Cycle 24: reconstruction of the global scenario and geoeffectiveness

Author

Scolini, Camilla, Messerotti, Mauro, Poedts, Stefaan, and Rodriguez, Luciano

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

In this study we present a statistical analysis of 53 fast Earth-directed halo CMEs observed by the SOHO/LASCO instrument during the period Jan. 2009-Sep. 2015, and we use this CME sample to test the capabilities of a Sun-to-Earth prediction scheme for CME geoeffectiveness. First, we investigate the CME association with other solar activity features by means of multi-instrument observations of the solar magnetic and plasma properties. Second, using coronagraphic images to derive the CME kinematical properties at 0.1 AU, we propagate the events to 1 AU by means of the WSA-ENLIL+Cone model. Simulation results at Earth are compared with in-situ observations at L1. By applying the pressure balance condition at the magnetopause and a solar wind-Kp index coupling function, we estimate the expected magnetospheric compression and geomagnetic activity level, and compare them with global data records. The analysis indicates that 82% of the CMEs arrived at Earth in the next 4 days. Almost the totality of them compressed the magnetopause below geosynchronous orbits and triggered a geomagnetic storm. Complex sunspot-rich active regions associated with energetic flares result the most favourable configurations from which geoeffective CMEs originate. The analysis of related SEP events shows that 74% of the CMEs associated with major SEPs were geoeffective. Moreover, the SEP production is enhanced in the case of fast and interacting CMEs. In this work we present a first attempt at applying a Sun-to-Earth geoeffectiveness prediction scheme - based on 3D simulations and solar wind-geomagnetic activity coupling functions - to a statistical set of potentially geoeffective halo CMEs. The results of the prediction scheme are in good agreement with geomagnetic activity data records, although further studies performing a fine-tuning of such scheme are needed., Comment: Accepted for publication in the Journal of Space Weather and Space Climate (SWSC)

Published

2017

32. Over-expansion of coronal mass ejections modelled using 3D MHD EUHFORIA simulations

Author

Verbeke, Christine, Schmieder, Brigitte, Démoulin, Pascal, Dasso, Sergio, Grison, Benjamin, Samara, Evangelia, Scolini, Camilla, and Poedts, Stefaan

Published

2022

33. Employing the Coupled EUHFORIA‐OpenGGCM Model to Predict CME Geoeffectiveness

Author

Maharana, Anwesha, primary, Cramer, W. Douglas, additional, Samara, Evangelia, additional, Scolini, Camilla, additional, Raeder, Joachim, additional, and Poedts, Stefaan, additional

Published

2024

34. On the Origin of the Sudden Heliospheric Open Magnetic Flux Enhancement During the 2014 Pole Reversal

Author

Heinemann, Stephan G., primary, Owens, Mathew J., additional, Temmer, Manuela, additional, Turtle, James A., additional, Arge, Charles N., additional, Henney, Carl J., additional, Pomoell, Jens, additional, Asvestari, Eleanna, additional, Linker, Jon A., additional, Downs, Cooper, additional, Caplan, Ronald M., additional, Hofmeister, Stefan J., additional, Scolini, Camilla, additional, Pinto, Rui F., additional, and Madjarska, Maria S., additional

Published

2024

35. The Space Weather Research on Coronal Mass Ejections Required Before Operational Sub-L1 Monitors

Author

Lugaz, Noé, primary, Regnault, Florian, additional, Banu, Sahanaj, additional, Al-Haddad, Nada, additional, Zhuang, Bin, additional, Lee, Christina, additional, Farrugia, Charles J., additional, Möstl, Christian, additional, Winslow, Reka M., additional, Davies, Emma, additional, Scolini, Camilla, additional, Yu, Wenyuan, additional, and Galvin, Toni, additional

Published

2024

36. The Width of Magnetic Ejecta Measured near 1 au: Lessons from STEREO-A Measurements in 2021–2022

Author

Lugaz, Noé, primary, Zhuang, Bin, additional, Scolini, Camilla, additional, Al-Haddad, Nada, additional, Farrugia, Charles J., additional, Winslow, Réka M., additional, Regnault, Florian, additional, Möstl, Christian, additional, Davies, Emma E., additional, and Galvin, Antoinette B., additional

Published

2024

37. On the Role of Alfvénic Fluctuations as Mediators of Coherence within Interplanetary Coronal Mass Ejections: Investigation of Multi-spacecraft Measurements at 1 au

Author

Scolini, Camilla, primary, Lugaz, Noé, additional, Winslow, Réka M., additional, Farrugia, Charles J., additional, Magyar, Norbert, additional, and Bacchini, Fabio, additional

Published

2024

38. The Effect of Magnetic Field Line Topology on ICME-related GCR Modulation

Author

Davies, Emma E., primary, Scolini, Camilla, additional, Winslow, Réka M., additional, Jordan, Andrew P., additional, and Möstl, Christian, additional

Published

2023

39. On the Contribution of Coronal Mass Ejections to the Heliospheric Magnetic Flux Budget on Different Time Scales

Author

Winslow, Réka M., primary, Scolini, Camilla, additional, Lugaz, Noé, additional, Schwadron, Nathan A., additional, and Galvin, Antoinette B., additional

Published

2023

40. Modeling a Coronal Mass Ejection from an Extended Filament Channel. II. Interplanetary Propagation to 1 au

Author

Palmerio, Erika, primary, Maharana, Anwesha, additional, Lynch, Benjamin J., additional, Scolini, Camilla, additional, Good, Simon W., additional, Pomoell, Jens, additional, Isavnin, Alexey, additional, and Kilpua, Emilia K. J., additional

Published

2023

41. Sensing CME Magnetic Fields En Route to 1 AU

Author

Wood, Brian E., primary, Kooi, Jason E., additional, Palmerio, Erika, additional, Gibson, Sarah E., additional, Lynch, Benjamin J., additional, Winslow, Réka M., additional, Jin, Meng, additional, Scolini, Camilla, additional, Jian, Lan K., additional, Török, Tibor, additional, Vourlidas, Angelos, additional, Gopalswamy, Nat, additional, Mostl, Christian, additional, Lee, Christina O., additional, Nieves-Chinchilla, Teresa, additional, Al-Haddad, Nada, additional, Lugaz, Noé, additional, Davies, Emma E., additional, Regnault, Florian, additional, and Farrugia, Charles J., additional

Published

2023

42. On the Need for a Coronal and Inner Heliospheric Panel for the 2024 Heliophysics Decadal Survey

Author

Al-Haddad, Nada, primary, Lugaz, Noé, additional, Palmerio, Erika, additional, Lynch, Benjamin J., additional, Nieves-Chinchilla, Teresa, additional, Jin, Meng, additional, Török, Tibor, additional, Carcaboso, Fernando, additional, Scolini, Camilla, additional, Regnault, Florian, additional, Lee, Christina O., additional, Davies, Emma E., additional, and Winslow, Réka M., additional

Published

2023

43. Learn to Walk Before You Run: A Case for Fundamental CME Research Utilizing Idealized MHD Models

Author

Török, Tibor, primary, Lugaz, Noé, additional, Lee, Christina O., additional, Palmerio, Erika, additional, Lynch, Benjamin J., additional, Winslow, Réka M., additional, Jin, Meng, additional, Nieves-Chinchilla, Teresa, additional, Al-Haddad, Nada, additional, Carcaboso, Fernando, additional, Davies, Emma E., additional, Farrugia, Charles J., additional, Jian, Lan K., additional, Manchester, Ward B., additional, Regnault, Florian, additional, Salman, Tarik M., additional, Scolini, Camilla, additional, Vourlidas, Angelos, additional, and Wood, Brian E., additional

Published

2023

44. The Multi-spacecraft Heliospheric Mission (MHM)

Author

Lugaz, Noé, primary, Lee, Christina O., additional, Jian, Lan K., additional, Allen, Robert, additional, Al-Haddad, Nada, additional, Winslow, Réka M., additional, Lillis, Rob, additional, Moestl, Christian, additional, Zhuang, Bin, additional, Palmerio, Erika, additional, Lynch, Benjamin J., additional, Scolini, Camilla, additional, Davies, Emma E., additional, Regnault, Florian, additional, Nieves-Chinchilla, Teresa, additional, and Farrugia, Charles J., additional

Published

2023

45. Work-Life Balance Starts with Proper Deadlines and Exemplary Agencies

Author

Lugaz, Noé, primary, Winslow, Réka M., additional, Al-Haddad, Nada, additional, Lee, Christina O., additional, Vines, Sarah, additional, Reeves, Katharine, additional, Caspi, Amir, additional, Seaton, Daniel, additional, Downs, Cooper, additional, Glesener, Lindsay, additional, Vourlidas, Angelos, additional, Scolini, Camilla, additional, Török, Tibor, additional, Allen, Robert, additional, and Palmerio, Erika, additional

Published

2023

46. The Multiview Observatory for Solar Terrestrial Science (MOST)

Author

Gopalswamy, Natchimuthuk, primary, Christe, Steven, additional, Fung, Shing, additional, Gong, Qian, additional, Jian, Lan, additional, Kanekal, Shrikanth, additional, Kay, Christina, additional, Kucera, Therese, additional, Leake, James, additional, Mäkelä, Pertti, additional, Shih, Albert, additional, Tadikonda, Sivakumar, additional, Viall, Nicholeen, additional, III, Lynn Wilson,, additional, Yashiro, Seiji, additional, Golub, Leon, additional, DeLuca, Edward, additional, Reeves, Kathy, additional, Sterling, Alphonse, additional, Savage, Sabrina, additional, Winebarger, Amy, additional, DeForest, Craig, additional, Desai, Mihir, additional, Seaton, Dan, additional, Lazio, Joseph, additional, Jensen, Elizabeth, additional, Manchester, Ward, additional, Sachdeva, Nishtha, additional, Wood, Brian, additional, Kooi, Jason, additional, Hess, Philip, additional, Wexler, David, additional, Bale, Stuart, additional, Krucker, Sam, additional, Hurlburt, Neal, additional, DeRosa, Marc, additional, Pevtsov, Alexei, additional, Petrie, Gordon, additional, Trpathy, Sushanta, additional, Jain, Kiran, additional, Gosain, Sanjay, additional, Kholikov, Shukur, additional, Zhao, Junwei, additional, Scherrer, Philip, additional, Rajaguru, Paul, additional, Woods, Tom, additional, Kenney, Megan, additional, Zhang, Jie, additional, Scolini, Camilla, additional, Cho, Kyungsuk, additional, and Park, Young-deuk, additional

Published

2023

47. New Observations Needed to Advance Our Understanding of Coronal Mass Ejections

Author

Palmerio, Erika, primary, Lynch, Benjamin J., additional, Lee, Christina O., additional, Jian, Lan K., additional, Nieves-Chinchilla, Teresa, additional, Davies, Emma E., additional, Wood, Brian E., additional, Lugaz, Noé, additional, Winslow, Réka M., additional, Török, Tibor, additional, Al-Haddad, Nada, additional, Regnault, Florian, additional, Jin, Meng, additional, Scolini, Camilla, additional, Carcaboso, Fernando, additional, Farrugia, Charles J., additional, Ledvina, Vincent E., additional, Downs, Cooper, additional, Kay, Christina, additional, Pal, Sanchita, additional, Salman, Tarik M., additional, and Allen, Robert C., additional

Published

2023

48. Heliophysics and Space Weather Science at ~1.5 AU: Knowledge Gaps and Need for Solar and Solar Wind Monitors at Mars

Author

Lee, Christina O., primary, Mayyasi, Majd, additional, Xu, Shaosui, additional, Chamberlin, Phillip, additional, DiBraccio, Gina, additional, Sanchez-Cano, Beatriz, additional, Davies, Emma E., additional, Scolini, Camilla, additional, Filwett, Rachael, additional, Ramstad, Robin, additional, Palmerio, Erika, additional, Lynch, Benjamin J., additional, Luhmann, Janet G., additional, Ehresmann, Bent, additional, Guo, Jingnan, additional, Allen, Robert C., additional, Vines, Sarah, additional, Winslow, Réka M., additional, and Elliott, Heather, additional

Published

2023

49. Connecting Solar and Stellar Flares/CMEs: Expanding Heliophysics to Encompass Exoplanetary Space Weather

Author

Lynch, Benjamin J., primary, Wood, Brian E., additional, Jin, Meng, additional, Török, Tibor, additional, Sun, Xudong, additional, Palmerio, Erika, additional, Osten, Rachel A., additional, Vidotto, Aline A., additional, Cohen, Ofer, additional, Alvarado-Gómez, Julián D., additional, Drake, Jeremy J., additional, Airapetian, Vladimir S., additional, Notsu, Yuta, additional, Veronig, Astrid, additional, Namekata, Kosuke, additional, Winslow, Réka M., additional, Jian, Lan K., additional, Vourlidas, Angelos, additional, Lugaz, Noé, additional, Al-Haddad, Nada, additional, Manchester, Ward B., additional, Scolini, Camilla, additional, Farrugia, Charles J., additional, Davies, Emma E., additional, Nieves-Chinchilla, Teresa, additional, Carcaboso, Fernando, additional, Lee, Christina O., additional, and Salman, Tarik M., additional

Published

2023

50. On the importance of investigating CME complexity evolution during interplanetary propagation

Author

Winslow, Réka M., primary, Lugaz, Noé, additional, Schmieder, Brigitte, additional, Temmer, Manuela, additional, Farrugia, Charles J., additional, Lavraud, Benoit, additional, Jian, Lan K., additional, Török, Tibor, additional, Vourlidas, Angelos, additional, Lee, Christina O., additional, Lynch, Benjamin J., additional, Poedts, Stefaan, additional, Wood, Brian E., additional, Palmerio, Erika, additional, Nieves-Chinchilla, Teresa, additional, Carcaboso, Fernando, additional, Regnault, Florian, additional, Scolini, Camilla, additional, Manchester, Ward B., additional, Al-Haddad, Nada, additional, Davies, Emma E., additional, Jin, Meng, additional, and Salman, Tarik M., additional

Published

2023