Your search keyword '"Réville, V."' showing total 41 results

1. Testing the flux tube expansion factor -- solar wind speed relation with Solar Orbiter data

Author

Dakeyo, J-B., Rouillard, A. P., Réville, V., Démoulin, P., Maksimovic, M., Chapiron, A., Pinto, R. F., and Louarn, P.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

The properties of the solar wind measured in-situ in the heliosphere are largely controlled by energy deposition in the solar. Previous studies have shown that long duration and large scale magnetic structures show an inverse relation between the solar wind velocity measured in situ near 1 au and the expansion factor of the magnetic flux tubes in the solar atmosphere. We exploit Solar Orbiter data in conjunction with the Potential Field Source Surface (PFSS) coronal model, and the solar wind trajectory to evaluate the flux expansion factor - speed relation at the solar "source surface" at rss. We find a statistically weak anti-correlation between the in-situ bulk velocity and the coronal expansion factor, for about 1.5 years of solar data. Classification of the data by source latitude reveals different levels of anticorrelation. We show the existence of fast solar wind that originates in strong magnetic field regions at low latitudes and undergoes large expansion factor. We provide evidence that such winds become supersonic during the super radial expansion (below rss), and are theoretically governed by a positive correlation v-f. We find that faster winds on average have a flux tube expansion at a larger radius than slower winds. An anticorrelation between solar wind speed and expansion factor is present for solar winds originating in high latitude structures in solar minimum activity, typically associated with coronal hole-like structures, but this cannot be generalized to lower latitude sources. Therefore, the value of the expansion factor alone cannot be used to predict the solar wind speed. Other parameters, such as the height at which the expansion gradient is the strongest must also be taken into account., Comment: 18 pages, 10 figures, 1 table

Published

2024

2. On Earth's habitability over the Sun's main-sequence history: joint influence of space weather and Earth's magnetic field evolution

Author

Varela, J., Brun, A. S., Strugarek, A., Reville, V., Zarka, P., and Pantellini, F.

Subjects

Astrophysics - Earth and Planetary Astrophysics, Physics - Space Physics

Abstract

The aim of this study is to analyze the Earth habitability with respect to the direct exposition of the Earth atmosphere to the solar wind along the Suns evolution on the main sequence including the realistic evolution of the space weather conditions and the Earth magnetic field. The MHD code PLUTO in spherical coordinates is applied to perform parametric studies with respect to the solar wind dynamic pressure and the interplanetary magnetic field intensity for different Earth magnetic field configurations. Quiet space weather conditions may not impact the Earth habitability. On the other hand, the impact of interplanetary coronal mass ejections (ICME) could lead to the erosion of the primary Earth atmosphere during the Hadean eon. A dipolar field of 30 microT is strong enough to shield the Earth from the Eo-Archean age as well as 15 and 5 microT dipolar fields from the Meso-Archean and Meso-Proterozoic, respectively. Multipolar weak field period during the Meso-Proterozoic age may not be a threat for ICME-like space weather conditions if the field intensity is at least 15 microT and the ratio between the quadrupolar (Q) and dipolar (D) coefficients is Q/D <= 0.5. By contrast, the Earth habitability in the Phanerozoic eon (including the present time) can be hampered during multipolar low field periods with a strength of 5 microT and Q/D >= 0.5 associated to geomagnetic reversals. Consequently, the effect of the solar wind should be considered as a possible driver of Earth's habitability.

Published

2023

3. MHD study of extreme space weather conditions for exoplanets with Earth-like magnetospheres: On habitability conditions and radio-emission

Author

Varela, J., Brun, A. S., Zarka, P., Strugarek, A., Pantellini, F., and Reville, V.

Subjects

Astrophysics - Earth and Planetary Astrophysics, Physics - Space Physics

Abstract

The present study aims at characterizing the habitability conditions of exoplanets with an Earth-like magnetosphere inside the habitable zone of M stars and F stars like tau Boo, caused by the direct deposition of the stellar wind on the exoplanet surface if the magnetosphere shielding is inefficient. In addition, the radio emission generated by exoplanets with a Earth-like magnetosphere is calculated for different space weather conditions. The study is based on a set of MHD simulations performed by the code PLUTO reproducing the space weather conditions expected for exoplanets orbiting the habitable zone of M stars and F stars type tau Boo. Exoplanets hosted by M stars at 0.2 au are protected from the stellar wind during regular and CME-like space weather conditions if the star rotation period is slower than 3 days, that is to say, faster rotators generate stellar winds and interplanetary magnetic fields large enough to endanger the exoplanet habitability. Exoplanets hosted by a F stars type tau Boo at >= 2.5 au are protected during regular space weather conditions, but a stronger magnetic field compared to the Earth is mandatory if the exoplanet is close to the inner edge of the star habitable zone (2.5 au) to shield the exoplanet surface during CME-like space weather conditions. The range of radio emission values calculated in the simulations are consistent with the scaling proposed by [Zarka 2018] during regular and common CME-like space weather conditions. If the radio telescopes measure a relative low radio emission signal with small variability from an exoplanet, that may indicate favorable exoplanet habitability conditions with respect to the space weather states considered and the intrinsic magnetic field of the exoplanet.

Published

2023

4. MOVES V. Modelling star-planet magnetic interactions of HD 189733

Author

Strugarek, A., Fares, R., Bourrier, V., Brun, A. S., Réville, V., Amari, T., Helling, Ch., Jardine, M., Llama, J., Moutou, C., Vidotto, A. A., Wheatley, P. J., and Zarka, P.

Subjects

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

Abstract

Magnetic interactions between stars and close-in planets may lead to a detectable signal on the stellar disk. HD 189733 is one of the key exosystems thought to harbor magnetic interactions, which may have been detected in August 2013. We present a set of twelve wind models at that period, covering the possible coronal states and coronal topologies of HD 189733 at that time. We assess the power available for the magnetic interaction and predict its temporal modulation. By comparing the predicted signal with the observed signal, we find that some models could be compatible with an interpretation based on star-planet magnetic interactions. We also find that the observed signal can be explained only with a stretch-and-break interaction mechanism, while that the Alfv\'en wings scenario cannot deliver enough power. We finally demonstrate that the past observational cadence of HD 189733 leads to a detection rate of only between 12 to 23%, which could explain why star-planet interactions have been hard to detect in past campaigns. We conclude that the firm confirmation of their detection will require dedicated spectroscopic observations covering densely the orbital and rotation period, combined with scarcer spectropolarimetric observations to assess the concomitant large-scale magnetic topology of the star., Comment: 16 pages, 8 figures, 4 tables, accepted for publication in MNRAS

Published

2022

5. MHD study of planetary magnetospheric response during extreme solar wind conditions: Earth and exoplanet magnetospheres applications

Author

Varela, J., Brun, A. S., Strugarek, A., Reville, V., Zarka, P., and Pantellini, F.

Subjects

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

Abstract

Context: The stellar wind and the interplanetary magnetic field modify the topology of planetary magnetospheres. Consequently, the hazardous effect of the direct exposition to the stellar wind, for example regarding the integrity of satellites orbiting the Earth or the habitability of exoplanets, depend upon the space weather conditions. Aims: The aim of the study is to analyze the response of an Earth-like magnetosphere for various space weather conditions and interplanetary coronal mass ejections. The magnetopause stand off distance, open-close field line boundary and plasma flows towards the planet surface are calculated. Methods: We use the MHD code PLUTO in spherical coordinates to perform a parametric study regarding the dynamic pressure and temperature of the stellar wind as well as the interplanetary magnetic field intensity and orientation. The range of the parameters analyzed extends from regular to extreme space weather conditions consistent with coronal mass ejections at the Earth orbit for the present and early periods of the Sun main sequence. In addition, implications of sub-Afvenic solar wind configurations for the Earth and exoplanet magnetospheres are analyzed. Results: The direct precipitation of the solar wind at the Earth day side in equatorial latitudes is extremely unlikely even during super coronal mass ejections. On the other hand, for early evolution phases along the Sun main sequence once the Sun rotation rate was at least $5$ times faster (< 440 Myr), the Earth surface was directly exposed to the solar wind during coronal mass ejections. Nowadays, satellites at High, Geosynchronous and Medium orbits are directly exposed to the solar wind during coronal mass ejections, because part of the orbit at the Earth day side is beyond the nose of the bow shock.

Published

2022

6. Two-dimensional simulations of solar-like models with artificially enhanced luminosity. II. Impact on internal gravity waves

Author

Saux, A. Le, Guillet, T., Baraffe, I., Vlaykov, D. G., Constantino, T., Pratt, J., Goffrey, T., Sylvain, M., Réville, V., and Brun, A. S.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Artificially increasing the luminosity and the thermal diffusivity of a model is a common tactic adopted in hydrodynamical simulations of stellar convection. In this work, we analyse the impact of these artificial modifications on the physical properties of stellar interiors and specifically on internal gravity waves. We perform two-dimensional simulations of solar-like stars with the MUSIC code. We compare three models with different luminosity enhancement factors to a reference model. The results confirm that properties of the waves are impacted by the artificial enhancement of the luminosity and thermal diffusivity. We find that an increase in the stellar luminosity yields a decrease in the bulk convective turnover timescale and an increase in the characteristic frequency of excitation of the internal waves. We also show that a higher energy input in a model, corresponding to a larger luminosity, results in higher energy in high frequency waves. Across our tests with the luminosity and thermal diffusivity enhanced together by up to a factor of 104, our results are consistent with theoretical predictions of radiative damping. Increasing the luminosity also has an impact on the amplitude of oscillatory motions across the convective boundary. One must use caution when interpreting studies of internal gravity waves based on hydrodynamical simulations with artificially enhanced luminosity., Comment: 16 pages, 13 figures; accepted for publication in A&A

Published

2022

7. Flux ropes and dynamics of the heliospheric current sheet

Author

Réville, V., Fargette, N., Rouillard, A. P., Lavraud, B., Velli, M., Strugarek, A., Parenti, S., Brun, A. S., Shi, C., Kouloumvakos, A., Poirier, N., Pinto, R. F., Louarn, P., Fedorov, A., Owen, C. J., Génot, V., Horbury, T. S., Laker, R., O'Brien, H., Angelini, V., Fauchon-Jones, E., and Kasper, J. C.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics

Abstract

Context. Solar Orbiter and PSP jointly observed the solar wind for the first time in June 2020, capturing data from very different solar wind streams, calm and Alfv\'enic wind as well as many dynamic structures. Aims. The aim here is to understand the origin and characteristics of the highly dynamic solar wind observed by the two probes, in particular in the vicinity of the heliospheric current sheet (HCS). Methods. We analyse the plasma data obtained by PSP and Solar Orbiter in situ during the month of June 2020. We use the Alfv\'en-wave turbulence MHD solar wind model WindPredict-AW, and perform two 3D simulations based on ADAPT solar magnetograms for this period. Results. We show that the dynamic regions measured by both spacecraft are pervaded with flux ropes close to the HCS. These flux ropes are also present in the simulations, forming at the tip of helmet streamers, i.e. at the base of the heliospheric current sheet. The formation mechanism involves a pressure driven instability followed by a fast tearing reconnection process, consistent with the picture of R\'eville et al. (2020a). We further characterize the 3D spatial structure of helmet streamer born flux ropes, which seems, in the simulations, to be related to the network of quasi-separatrices., Comment: 14 pages, 12 Figures, accepted for publication in Astronomy and Astrophysics

Published

2021

8. Magnetic reconnection as a mechanism to produce multiple protonpopulations and beams locally in the solar wind

Author

Lavraud, B., Kieokaew, R., Fargette, N., Louarn, P., Fedorov, A., André, N., Fruit, G., Génot, V., Réville, V., Rouillard, A. P., Plotnikov, I., Penou, E., Barthe, A., Prech, L., Owen, C. J., Bruno, R., Allegrini, F., Berthomier, M., Kataria, D., Livi, S., Raines, J. M., D'Amicis, R., Eastwood, J. P., Froment, C., Laker, R., Maksimovic, M., Marcucci, F., Perri, S., Perrone, D., Phan, T. D., Stansby, D., Stawarz, J., Redondo, S. Toledo, Vaivads, A., Verscharen, D., Zouganelis, I., Angelini, V., Evans, V., Horbury, T. S., and O'brien, H.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

Context. Spacecraft observations early revealed frequent multiple proton populations in the solar wind. Decades of research on their origin have focused on processes such as magnetic reconnection in the low corona and wave-particle interactions in the corona and locally in the solar wind.Aims.This study aims to highlight that multiple proton populations and beams are also produced by magnetic reconnection occurring locally in the solar wind. Methods. We use high resolution Solar Orbiter proton velocity distribution function measurements, complemented by electron and magnetic field data, to analyze the association of multiple proton populations and beams with magnetic reconnection during a period of slow Alfv\'enic solar wind on 16 July 2020. Results. At least 6 reconnecting current sheets with associated multiple proton populations and beams, including a case of magnetic reconnection at a switchback boundary, are found during this day. This represents 2% of the measured distribution functions. We discuss how this proportion may be underestimated, and how it may depend on solar wind type and distance from the Sun. Conclusions. Although suggesting a likely small contribution, but which remains to be quantitatively assessed, Solar Orbiter observations show that magnetic reconnection must be considered as one of the mechanisms that produce multiple proton populations and beams locally in the solar wind.

Published

2021

9. Chasing star-planet magnetic interactions: the case of Kepler-78

Author

Strugarek, A., Brun, A. S., Donati, J. -F., Moutou, C., and Réville, V.

Subjects

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

Abstract

Observational evidence of star-planet magnetic interactions (SPMI) in compact exo-systems have been looked for in the past decades. Indeed planets in close-in orbit can be magnetically connected to their host star, and channel Alfv\'en waves carrying large amounts of energy towards the central star. The strength and temporal modulation of SPMIs are primarily set by the magnetic topology of the host star and the orbital characteristics of the planet. As a result, SPMI signals can be modulated over the rotational period of the star, the orbital period of the planet, or a complex combination of the two. The detection of SPMI thus have to rely on multiple-epochs and multiple-wavelengths observational campaigns. We present a new method to characterize SPMIs and apply it to Kepler-78, a late G star with a super-Earth on an 8.5 hours orbit. We model the corona of Kepler-78 using the large-scale magnetic topology of the star observed with Zeeman-Doppler-Imaging. We show that the closeness of Kepler-78b allows the interaction to channel energy flux densities up to a few kW m$^{-2}$ towards the central star. We show that this flux is large enough to be detectable in classical activity tracers such as H$\alpha$. It is nonetheless too weak to explain the modulation observed by \citet{Moutou2016}. We furthermore demonstrate how to predict the temporal modulation of SPMI signals in observed systems such as Kepler-78. The methodology presented here thus paves the road towards denser, specific observational campaigns that would allow a proper identification of SPMIs in compact star-planet systems., Comment: 16 pages, 11 figures, 2 tables, accepted for publication in The Astrophysical Journal

Published

2019

10. Reconstructing Extreme Space Weather from Planet Hosting Stars

Author

Airapetian, V. S., Adibekyan, V., Ansdell, M., Alexander, D., Bastian, T., Saikia, S. Boro, Brun, A. S., Cohen, O., Cuntz, M., Danchi, W., Davenport, J., DeNolfo, J., DeVore, R., Dong, C. F., Drake, J. J., France, K., Fraschetti, F., Herbst, K., Garcia-Sage, K., Gillon, M., Glocer, A., Grenfell, J. L., Gronoff, G., Gopalswamy, N., Guedel, M., Hartnett, H., Harutyunyan, H., Hinkel, N. R., Jensen, A. G., Jin, M., Johnstone, C., Kalas, P., Kane, S. R., Kay, C., Kitiashvili, I. N., Kochukhov, O., Kondrashov, D., Lazio, J., Leake, J., Li, G., Linsky, J., Lueftinger, T., Lynch, B., Lyra, W., Mandell, A. M., Mandt, K. E., Maehara, H., Miesch, M. S., Mickaelian, A. M., Mouchou, S., Notsu, Y., Ofman, L., Oman, L. D., Osten, R. A., Oran, R., Petre, R., Ramirez, R. M., Rau, G., Redfield, S., Réville, V., Rugheimer, S., Scheucher, M., Schlieder, J. E., Shibata, K., Schnittman, J. D., Soderblom, David, Strugarek, A., Turner, J. D., Usmanov, A., Der Holst, Van, Vidotto, A., Vourlidas, A., Way, M. J., Wolk, Zank, G. P., R., P. Zarka, Kopparapu, Babakhanova, S., Pevtsov, A. A., Lee, Y., Henning, W., Colón, K. D., and Wolf, E. T.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

The field of exoplanetary science is making rapid progress both in statistical studies of exoplanet properties as well as in individual characterization. As space missions provide an emerging picture of formation and evolution of exoplanetary systems, the search for habitable worlds becomes one of the fundamental issues to address. To tackle such a complex challenge, we need to specify the conditions favorable for the origin, development and sustainment of life as we know it. This requires the understanding of global (astrospheric) and local (atmospheric, surface and internal) environments of exoplanets in the framework of the physical processes of the interaction between evolving planet-hosting stars along with exoplanetary evolution over geological timescales, and the resulting impact on climate and habitability of exoplanets. Feedbacks between astrophysical, physico-chemical atmospheric and geological processes can only be understood through interdisciplinary studies with the incorporation of progress in heliophysics, astrophysics, planetary, Earth sciences, astrobiology, and the origin of life communities. The assessment of the impacts of host stars on the climate and habitability of terrestrial (exo)planets and potential exomoons around them may significantly modify the extent and the location of the habitable zone and provide new directions for searching for signatures of life. Thus, characterization of stellar ionizing outputs becomes an important task for further understanding the extent of habitability in the universe. The goal of this white paper is to identify and describe promising key research goals to aid the theoretical characterization and observational detection of ionizing radiation from quiescent and flaring upper atmospheres of planet hosts as well as properties of stellar coronal mass ejections and stellar energetic particle events., Comment: White Paper submitted to the Astronomy and Astrophysics Decadal Survey (Astro2020), 8 pages, 1 figure

Published

2019

11. Evolution of star-planet systems under magnetic braking and tidal interaction

Author

Benbakoura, M., Réville, V., Brun, A. S., Poncin-Lafitte, C. Le, and Mathis, S.

Subjects

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

Abstract

With the discovery over the last two decades of a large diversity of exoplanetary systems, it is now of prime importance to characterize star-planet interactions and how such systems evolve. We address this question by studying systems formed by a solar-like star and a close-in planet. We focus on the stellar wind spinning down the star along its main sequence phase and tidal interaction causing orbital evolution of the systems. Despite recent significant advances in these fields, all current models use parametric descriptions to study at least one of these effects. Our objective is to introduce simultaneously ab-initio prescriptions of the tidal and braking torques, so as to improve our understanding of the underlying physics. We develop a 1D numerical model of coplanar circular star-planet systems taking into account stellar structural changes, wind braking and tidal interaction and implement it in a code called ESPEM. We follow the secular evolution of the stellar rotation assuming a bi-layer internal structure, and of the semi-major axis of the orbit. After comparing our predictions to recent observations and models, we perform tests to emphasize the contribution of ab-initio prescriptions. Our secular model of stellar wind braking reproduces well the recent observations of stellar rotation in open clusters. Our results show that a planet can affect the rotation of its host star and that the resulting spin-up or spin-down depends on the orbital semi-major axis and on the joint influence of magnetic and tidal effects. The ab-initio prescription for tidal dissipation that we used predicts fast outward migration of massive planet orbiting fast-rotating young stars. Finally, we provide the reader with a criterion based on the system's characteristics that allows us to assess whether or not the planet will undergo orbital decay due to tidal interaction., Comment: Accepted for publication in Astronomy & Astrophysics

Published

2018

12. Effect of the exoplanet magnetic field topology on its magnetospheric radio emission

Author

Varela, J., Réville, V., Brun, A. S., Zarka, P., and Pantellini, F.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

The magnetized wind from stars that impact exoplanets should lead to radio emissions. According to the scaling laws derived in the solar system, the radio emission should depend on the stellar wind, interplanetary magnetic field, and topology of the exoplanet magnetosphere. The aim of this study is to calculate the dissipated power and subsequent radio emission from exoplanet magnetospheres with different topologies perturbed by the interplanetary magnetic field and stellar wind, to refine the predictions from scaling laws, and to prepare the interpretation of future radio detections. We use the magnetohydrodynamic (MHD) code PLUTO in spherical coordinates to analyze the total radio emission level resulting from the dissipation of the kinetic and magnetic (Poynting flux) energies inside the exoplanet's magnetospheres. We apply a formalism to infer the detailed contribution in the exoplanet radio emission on the exoplanet's day side and magnetotail. The model is based on Mercury-like conditions, although the study results are extrapolated to exoplanets with stronger magnetic fields, providing the lower bound of the radio emission. The predicted dissipated powers and resulting radio emissions depends critically on the exoplanet magnetosphere topology and interplanetary magnetic field (IMF) orientation. The radio emission on the exoplanet's night and day sides should thus contain information on the exoplanet magnetic field topology. In addition, if the topology of an exoplanet magnetosphere is known, the radio emission measurements can be used as a proxy of the instantaneous dynamic pressure of the stellar wind, IMF orientation, and intensity.

Published

2018

13. The fate of close-in planets: tidal or magnetic migration?

Author

Strugarek, A., Bolmont, E., Mathis, S., Brun, A. S., Réville, V., Gallet, F., and Charbonnel, C.

Subjects

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

Abstract

Planets in close-in orbits interact magnetically and tidally with their host stars. These interactions lead to a net torque that makes close-in planets migrate inward or outward depending on their orbital distance. We compare systematically the strength of magnetic and tidal torques for typical observed star-planet systems (T-Tauri & hot Jupiter, M dwarf & Earth-like planet, K star & hot Jupiter) based on state-of-the-art scaling-laws. We find that depending on the characteristics of the system, tidal or magnetic effects can dominate. For very close-in planets, we find that both torques can make a planet migrate on a timescale as small as 10 to 100 thousands of years. Both effects thus have to be taken into account when predicting the evolution of compact systems., Comment: 9 pages, 2 figures, 1 table, accepted for publication in The Astrophysical Journal Letters

Published

2017

14. Impact of far-side structures observed by Solar Orbiter on coronal and heliospheric wind simulations

Author

Perri, B., primary, Finley, A., additional, Réville, V., additional, Parenti, S., additional, Brun, A.S., additional, Strugarek, A., additional, and Buchlin, É., additional

Published

2024

15. Radial evolution of the accuracy of ballistic solar wind backmapping

Author

Dakeyo, J-B., primary, Badman, S.T., additional, Rouillard, A.P., additional, Réville, V., additional, Verscharen, D., additional, Démoulin, P., additional, and Maksimovic, M., additional

Published

2024

16. Radio emission in Mercury magnetosphere

Author

Varela, J., Reville, V., Brun, A. S., Pantellini, F., and Zarka, P.

Subjects

Astrophysics - Earth and Planetary Astrophysics, Physics - Space Physics

Abstract

Context: Active stars possess magnetized wind that has a direct impact on planets that can lead to radio emission. Mercury is a good test case to study the effect of the solar wind and interplanetary magnetic field on radio emission driven in the planet magnetosphere. Such studies could be used as proxies to characterize the magnetic field topology and intensity of exoplanets. Aims: The aim of this study is to quantify the radio emission in the Hermean magnetosphere. Methods: We use the MHD code PLUTO in spherical coordinates with an axisymmetric multipolar expansion for the Hermean magnetic field, to analyze the effect of the interplanetary magnetic field (IMF) orientation and intensity, as well as the hydrodynamic parameters of the solar wind (velocity, density and temperature), on the net power dissipated on the Hermean day and night side. We apply the formalism derived by Zarka [2001, 2007] to infer the radio emission level from the net dissipated power. We perform a set of simulations with different hydrodynamic parameters of the solar wind, IMF orientations and intensities, that allow us to calculate the dissipated power distribution and infer the existence of radio emission hot spots on the planet day side, and to calculate the integrated radio emission of the Hermean magnetosphere. Results: The obtained radio emission distribution of dissipated power is determined by the IMF orientation (associated with the reconnection regions in the magnetosphere), although the radio emission strength is dependent on the IMF intensity and solar wind hydro parameters. The calculated total radio emission level is in agreement with the one estimated in [Zarka, 2001], between $5 \times 10^{5}$ and $2 \times 10^{6}$ W.

Published

2016

17. Magnetic games between a planet and its host star: the key role of topology

Author

Strugarek, A., Brun, A. S., Matt, S. P., and Réville, V.

Subjects

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

Abstract

Magnetic interactions between a star and a close-in planet are postulated to be a source of enhanced emissions and to play a role in the secular evolution of the orbital system. Close-in planets generally orbit in the sub-alfv\'enic region of the stellar wind, which leads to efficient transfers of energy and angular momentum between the star and the planet. We model the magnetic interactions occurring in close-in star-planet systems with three-dimensional, global, compressible magneto-hydrodynamic numerical simulations of a planet orbiting in a self-consistent stellar wind. We focus on the cases of magnetized planets and explore three representative magnetic configurations. The Poynting flux originating from the magnetic interactions is an energy source for enhanced emissions in star-planet systems. Our results suggest a simple geometrical explanation for ubiquitous on/off enhanced emissions associated with close-in planets, and confirm that the Poynting fluxes can reach powers of the order of $10^{19}$ W. Close-in planets are also showed to migrate due to magnetic torques for sufficiently strong stellar wind magnetic fields. The topology of the interaction significantly modifies the shape of the magnetic obstacle that leads to magnetic torques. As a consequence, the torques can vary by at least an order of magnitude as the magnetic topology of the interaction varies., Comment: 15 pages, 6 figures, accepted for publication in The Astrophysical Journal

Published

2015

18. Numerical aspects of 3D stellar winds

Author

Strugarek, A., Brun, A. S., Matt, S. P., and Reville, V.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

This paper explores and compares the pitfalls of modelling the three-dimensional wind of a spherical star with a cartesian grid. Several numerical methods are compared, using either uniform and stretched grid or adaptative mesh refinement (AMR). An additional numerical complication is added, when an orbiting planet is considered. In this case a rotating frame is added to the model such that the orbiting planet is at rest in the frame of work. The three-dimensional simulations are systematically compared to an equivalent two-dimensional, axisymmetric simulation. The comparative study presented here suggests to limit the rotation rate of the rotating frame below the rotating frame of the star and provides guidelines for further three-dimensional modelling of stellar winds in the context of close-in star-planet interactions., Comment: 11 pages, 3 figures, 3 tables, to appear in the CoolStars 18 Proceedings

Published

2014

19. Cool Stars and Space Weather

Author

Vidotto, A. A., Jardine, M., Cameron, A. C., Morin, J., Villadsen, J., Saar, S., Alvarado, J., Cohen, O., Holzwarth, V., Poppenhaeger, K., and Reville, V.

Subjects

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

Abstract

Stellar flares, winds and coronal mass ejections form the space weather. They are signatures of the magnetic activity of cool stars and, since activity varies with age, mass and rotation, the space weather that extra-solar planets experience can be very different from the one encountered by the solar system planets. How do stellar activity and magnetism influence the space weather of exoplanets orbiting main-sequence stars? How do the environments surrounding exoplanets differ from those around the planets in our own solar system? How can the detailed knowledge acquired by the solar system community be applied in exoplanetary systems? How does space weather affect habitability? These were questions that were addressed in the splinter session "Cool stars and Space Weather", that took place on 9 Jun 2014, during the Cool Stars 18 meeting. In this paper, we present a summary of the contributions made to this session., Comment: Proceedings of the 18th Cambridge Workshop on Cool Stars, Stellar Systems, and the Sun, Eds G. van Belle & H. Harris, 13 pages, 1 figure

Published

2014

20. On Earth’s habitability over the Sun’s main-sequence history: joint influence of space weather and Earth’s magnetic field evolution

Author

Varela, J, primary, Brun, A S, additional, Strugarek, A, additional, Réville, V, additional, Zarka, P, additional, and Pantellini, F, additional

Published

2023

21. Skewness and kurtosis of solar wind proton distribution functions: The normal inverse-Gaussian model and its implications.

Author

Louarn, P., Fedorov, A., Prech, L., Owen, C. J., D'Amicis, R., Bruno, R., Livi, S., Lavraud, B., Rouillard, A. P., Génot, V., André, N., Fruit, G., Réville, V., Kieokaew, R., Plotnikov, I., Penou, E., Barthe, A., Lewis, G., Berthomier, M., and Allegrini, F.

Subjects

DISTRIBUTION (Probability theory), SOLAR wind, ASTROPHYSICAL fluid dynamics, KURTOSIS, GAUSSIAN distribution

Abstract

Context. In the solar wind (SW), the particle distribution functions are generally not Gaussian. They present nonthermal features that are related to underlying acceleration and heating processes. These processes are critical in the overall dynamics of this expanding astrophysical fluid. Aims. The Proton Alpha Sensor (PAS) on board Solar Orbiter commonly observes skewed proton distributions, with a more populated high-energy side in the magnetic field direction than the Gaussian distribution. Our objectives are: (1) to identify a theoretical statistical function that adequately models the observed distributions and (2) to use its statistical interpretation to constrain the acceleration and heating processes. Methods. We analyzed the 3D velocity distribution functions (VDFs) measured by PAS and compared them to model statistical functions. Results. We show that the normal inverse Gaussian (NIG), a type of hyperbolic statistical distribution, provides excellent fits of skewed and leptokurtic proton distributions. NIG can model both the core distribution and the beam, if present. We propose an interpretation that is inspired by the mathematical formulation of the NIG. It assumes that the acceleration or heating mechanism can be modeled as a drifting diffusion process in velocity space, controlled (or subordinated) by the time of interaction of the particles with "accelerating structures". The probability function of the interaction time is an inverse Gaussian (IG), obtained by considering a random drift across structures of a given size. The control of the diffusion by interaction times that follow an IG probability function formally defines the NIG distribution. Following this model, we show that skewness and kurtosis can be used to estimate the kinetic and thermal energy gains provided by the interaction with structures. For example, in the case studies presented here, the analyzed populations would have gained kinetic energy representing approximately two to four times their thermal energy, with an increase in velocity – due to acceleration – of from one-tenth to one-third of the observed flow velocity. We also show that the model constrains the initial temperature of the populations. Conclusions. Overall, the NIG model offers excellent fits of the observed proton distributions. Combining the skewness and the kurtosis, it also leads to constraints in the part of acceleration and heating due to the interactions with structures in the formation of the proton populations. We suggest that these effects add to the classical thermal evolution of the bulk velocity and temperature resulting from SW expansion. [ABSTRACT FROM AUTHOR]

Published

2024

22. MHD Study of Extreme Space Weather Conditions for Exoplanets With Earth‐Like Magnetospheres: On Habitability Conditions and Radio‐Emission

Author

Varela, J., primary, Brun, A. S., additional, Zarka, P., additional, Strugarek, A., additional, Pantellini, F., additional, and Réville, V., additional

Published

2022

23. Two-dimensional simulations of solar-like models with artificially enhanced luminosity

Author

Le Saux, A., primary, Guillet, T., additional, Baraffe, I., additional, Vlaykov, D. G., additional, Constantino, T., additional, Pratt, J., additional, Goffrey, T., additional, Sylvain, M., additional, Réville, V., additional, and Brun, A. S., additional

Published

2022

24. MOVES – V. Modelling star–planet magnetic interactions of HD 189733

Author

Strugarek, A, primary, Fares, R, additional, Bourrier, V, additional, Brun, A S, additional, Réville, V, additional, Amari, T, additional, Helling, Ch, additional, Jardine, M, additional, Llama, J, additional, Moutou, C, additional, Vidotto, A A, additional, Wheatley, P J, additional, and Zarka, P, additional

Published

2022

25. Flux rope and dynamics of the heliospheric current sheet

Author

Réville, V., primary, Fargette, N., additional, Rouillard, A. P., additional, Lavraud, B., additional, Velli, M., additional, Strugarek, A., additional, Parenti, S., additional, Brun, A. S., additional, Shi, C., additional, Kouloumvakos, A., additional, Poirier, N., additional, Pinto, R. F., additional, Louarn, P., additional, Fedorov, A., additional, Owen, C. J., additional, Génot, V., additional, Horbury, T. S., additional, Laker, R., additional, O’Brien, H., additional, Angelini, V., additional, Fauchon-Jones, E., additional, and Kasper, J. C., additional

Published

2022

26. MHD study of the planetary magnetospheric response during extreme solar wind conditions: Earth and exoplanet magnetospheres applications

Author

Varela, J., primary, Brun, A. S., additional, Strugarek, A., additional, Réville, V., additional, Zarka, P., additional, and Pantellini, F., additional

Published

2022

27. Magnetic reconnection as a mechanism to produce multiple thermal proton populations and beams locally in the solar wind

Author

Lavraud, B., primary, Kieokaew, R., additional, Fargette, N., additional, Louarn, P., additional, Fedorov, A., additional, André, N., additional, Fruit, G., additional, Génot, V., additional, Réville, V., additional, Rouillard, A. P., additional, Plotnikov, I., additional, Penou, E., additional, Barthe, A., additional, Prech, L., additional, Owen, C. J., additional, Bruno, R., additional, Allegrini, F., additional, Berthomier, M., additional, Kataria, D., additional, Livi, S., additional, Raines, J. M., additional, D’Amicis, R., additional, Eastwood, J. P., additional, Froment, C., additional, Laker, R., additional, Maksimovic, M., additional, Marcucci, F., additional, Perri, S., additional, Perrone, D., additional, Phan, T. D., additional, Stansby, D., additional, Stawarz, J., additional, Toledo-Redondo, S., additional, Vaivads, A., additional, Verscharen, D., additional, Zouganelis, I., additional, Angelini, V., additional, Evans, V., additional, Horbury, T. S., additional, and O’Brien, H., additional

Published

2021

28. Multiscale views of an Alfvénic slow solar wind: 3D velocity distribution functions observed by the Proton-Alpha Sensor of Solar Orbiter

Author

Louarn, P., primary, Fedorov, A., additional, Prech, L., additional, Owen, C. J., additional, Bruno, R., additional, Livi, S., additional, Lavraud, B., additional, Rouillard, A. P., additional, Génot, V., additional, André, N., additional, Fruit, G., additional, Réville, V., additional, Kieokaew, R., additional, Plotnikov, I., additional, Penou, E., additional, Barthe, A., additional, Khataria, D., additional, Berthomier, M., additional, D’Amicis, R., additional, Sorriso-Valvo, L., additional, Allegrini, F., additional, Raines, J., additional, Verscharen, D., additional, Fortunato, V., additional, Mele, G., additional, Horbury, T. S., additional, O’brien, H., additional, Evans, V., additional, Angelini, V., additional, Maksimovic, M., additional, Kasper, J. C., additional, and Bale, S. D., additional

Published

2021

29. Alfvénic versus non-Alfvénic turbulence in the inner heliosphere as observed by Parker Solar Probe

Author

Shi, C., primary, Velli, M., additional, Panasenco, O., additional, Tenerani, A., additional, Réville, V., additional, Bale, S. D., additional, Kasper, J., additional, Korreck, K., additional, Bonnell, J. W., additional, Dudok de Wit, T., additional, Malaspina, D. M., additional, Goetz, K., additional, Harvey, P. R., additional, MacDowall, R. J., additional, Pulupa, M., additional, Case, A. W., additional, Larson, D., additional, Verniero, J. L., additional, Livi, R., additional, Stevens, M., additional, Whittlesey, P., additional, Maksimovic, M., additional, and Moncuquet, M., additional

Published

2021

30. The Heliospheric Current Sheet and Plasma Sheet during Parker Solar Probe’s First Orbit

Author

Lavraud, B., primary, Fargette, N., additional, Réville, V., additional, Szabo, A., additional, Huang, J., additional, Rouillard, A. P., additional, Viall, N., additional, Phan, T. D., additional, Kasper, J. C., additional, Bale, S. D., additional, Berthomier, M., additional, Bonnell, J. W., additional, Case, A. W., additional, Dudok de Wit, T., additional, Eastwood, J. P., additional, Génot, V., additional, Goetz, K., additional, Griton, L. S., additional, Halekas, J. S, additional, Harvey, P., additional, Kieokaew, R., additional, Klein, K. G., additional, Korreck, K. E., additional, Kouloumvakos, A., additional, Larson, D. E., additional, Lavarra, M., additional, Livi, R., additional, Louarn, P., additional, MacDowall, R. J., additional, Maksimovic, M., additional, Malaspina, D., additional, Nieves-Chinchilla, T., additional, Pinto, R. F., additional, Poirier, N., additional, Pulupa, M., additional, Raouafi, N. E., additional, Stevens, M. L., additional, Toledo-Redondo, S., additional, and Whittlesey, P. L., additional

Published

2020

31. Reconstructing Extreme Space Weather From Planet Hosting Stars

Author

Airapetian, V., Adibekyan, V., Ansdell, M., Alexander, D., Barklay, T., Bastian, T., Boro Saikia, S., Cohen, O., Cuntz, M., Danchi, W., Davenport, J., DeNolfo, G., DeVore, R., Dong, C., Drake, J., France, K., Fraschetti, F., Herbst, K., Garcia-Sage, K., Gillon, M., Glocer, A., Grenfell, J., Gronoff, G., Gopalswamy, N., Guedel, M., Hartnett, H., Harutyunyan, H., Hinkel, N., Jensen, A., Jin, M., Johnstone, C., Kahler, S., Kalas, P., Kane, S., Kay, C., Kitiashvili, I., Kochukhov, O., Kondrashov, D., Lazio, J., Leake, J., Li, G., Linsky, J., Lueftinger, T., Lynch, B., Lyra, W., Mandell, A., Mandt, K., Maehara, H., Miesch, M., Mickaelian, A., Mouschou, S., Notsu, Y., Ofman, L., Oman, L., Osten, R., Oran, R., Petre, R., Ramirez, R., Rau, G., Redfield, S., Réville, V., Rugheimer, S., Scheucher, M., Schlieder, J., Shibata, K., Schnittman, J., Soderblom, D., Strugarek, A., Turner, J., Usmanov, A., Van Der Holst, B., Vidotto, A., Vourlidas, A., Way, M., Wolk, S., Zank, G., Zarka, P., Kopparapu, R., Babakhanova, S., Pevtsov, A., Lee, Y., Henning, W., Colón, K., and Wolf, E.

Subjects

Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics::Earth and Planetary Astrophysics, Astrophysics::Galaxy Astrophysics

Abstract

The goal of this white paper is to identify and describe promising key research goals to aid the theoretical characterization and observational detection of ionizing radiation from quiescent and flaring upper atmospheres of planet hosts as well as properties of stellar coronal mass ejections (CMEs) and stellar energetic particle (SEP) events.

Published

2019

32. Chasing Star–Planet Magnetic Interactions: The Case of Kepler-78

Author

Strugarek, A., primary, Brun, A. S., additional, Donati, J.-F., additional, Moutou, C., additional, and Réville, V., additional

Published

2019

33. Spin evolution and saturation: new insights through 3D MHD simulations of young solar analogs

Author

Réville, V., primary and Brun, A.S., additional

Published

2019

34. Evolution of star–planet systems under magnetic braking and tidal interaction

Author

Benbakoura, M., primary, Réville, V., additional, Brun, A. S., additional, Le Poncin-Lafitte, C., additional, and Mathis, S., additional

Published

2019

35. Simulations of solar wind variations during an 11-year cycle and the influence of north–south asymmetry

Author

Perri, B., primary, Brun, A. S., additional, Réville, V., additional, and Strugarek, A., additional

Published

2018

36. Effect of the exoplanet magnetic field topology on its magnetospheric radio emission

Author

Varela, J., primary, Réville, V., additional, Brun, A. S., additional, Zarka, P., additional, and Pantellini, F., additional

Published

2018

37. The Fate of Close-in Planets: Tidal or Magnetic Migration?

Author

Strugarek, A., primary, Bolmont, E., additional, Mathis, S., additional, Brun, A. S., additional, Réville, V., additional, Gallet, F., additional, and Charbonnel, C., additional

Published

2017

38. A space weather information service based upon remote and in-situ measurements of coronal mass ejections heading for earth

Author

Ritter, B. (author), Meskers, A.J.H. (author), Miles, O. (author), Russwurm, M. (author), Scully, S. (author), Roldan, A. (author), Hartkorn, O. (author), Jüstel, P. (author), Réville, V. (author), Lupu, S. (author), Ruffenach, A. (author), Ritter, B. (author), Meskers, A.J.H. (author), Miles, O. (author), Russwurm, M. (author), Scully, S. (author), Roldan, A. (author), Hartkorn, O. (author), Jüstel, P. (author), Réville, V. (author), Lupu, S. (author), and Ruffenach, A. (author)

Abstract

The Earth’s magnetosphere is formed as a consequence of interaction between the planet’s magnetic field and the solar wind, a continuous plasma stream from the Sun. A number of different solar wind phenomena have been studied over the past 40 years with the intention of understanding and forecasting solar behavior. One of these phenomena in particular, Earth-bound interplanetary coronal mass ejections (CMEs), can significantly disturb the Earth’s magnetosphere for a short time and cause geomagnetic storms. This publication presents a mission concept consisting of six spacecraft that are equally spaced in a heliocentric orbit at 0.72 AU. These spacecraft will monitor the plasma properties, the magnetic field’s orientation and magnitude, and the 3D-propagation trajectory of CMEs heading for Earth. The primary objective of this mission is to increase space weather forecasting time by means of a near real-time information service, that is based upon in-situ and remote measurements of the aforementioned CME properties. The obtained data can additionally be used for updating scientific models. This update is the mission’s secondary objective. In-situ measurements are performed using a Solar Wind Analyzer instrumentation package and fluxgate magnetometers, while for remote measurements coronagraphs are employed. The proposed instruments originate from other space missions with the intention to reduce mission costs and to streamline the mission design process. Communication with the six identical spacecraft is realized via a deep space network consisting of six ground stations. They provide an information service that is in uninterrupted contact with the spacecraft, allowing for continuous space weather monitoring. A dedicated data processing center will handle all the data, and then forward the processed data to the SSA Space Weather Coordination Center which will, in turn, inform the general public through a space weather forecast. The data processing center will addition, Precision and Microsystems Engineering, Mechanical, Maritime and Materials Engineering

Published

2015

39. MAGNETIC GAMES BETWEEN A PLANET AND ITS HOST STAR: THE KEY ROLE OF TOPOLOGY

Author

Strugarek, A., primary, Brun, A. S., additional, Matt, S. P., additional, and Réville, V., additional

Published

2015

40. Magnetic energy fluxes in close-in star-planet systems

Author

Strugarek, A., primary, Brun, A. S., additional, Matt, S. P., additional, and Réville, V., additional

Published

2015

41. ON THE DIVERSITY OF MAGNETIC INTERACTIONS IN CLOSE-IN STAR-PLANET SYSTEMS

Author

Strugarek, A., primary, Brun, A. S., additional, Matt, S. P., additional, and Réville, V., additional

Published

2014