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Main Authors: Peña-Moñino, Luis, Pérez-Torres, Miguel, Varela, Jacobo, Zarka, Philippe
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2405.19116
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author Peña-Moñino, Luis
Pérez-Torres, Miguel
Varela, Jacobo
Zarka, Philippe
author_facet Peña-Moñino, Luis
Pérez-Torres, Miguel
Varela, Jacobo
Zarka, Philippe
contents The habitability of exoplanets hosted by M-dwarf stars dramatically depends on their space weather. We present 3D magneto-hydrodynamic simulations to characterise the magneto-plasma environment and thus the habitability of the Earth-like planet Proxima b when it is subject to both calm and extreme (CME-like) space weather conditions. We study the role of the stellar wind and planetary magnetic field, and determine the radio emission arising from the interaction between the stellar wind of Proxima and the magnetosphere of its planet Proxima b. We find that if Prox b has a magnetic field similar to that of the Earth ($B_{\rm p} = B_\oplus \approx 0.32$ G) or larger, the magnetopause standoff distance is large enough to shield the surface from the stellar wind for essentially any planetary tilt but the most extreme values (close to $90^{\circ} $), under a calm space weather. Even if Proxima b is subject to more extreme space weather conditions, the planet is well shielded by an Earth-like magnetosphere ($B_{\rm p} \approx B_\oplus$; $ \approx 23.5^{\circ}$), or if it has tilt smaller than that of the Earth. For calm space weather conditions, the radio emission caused by the day-side reconnection regions can be as high as 7$\times10^{19}$ erg s$^{-1}$ in the super-Alfvénic regime, and is on average almost an order of magnitude larger than the radio emission in the sub-Alfvénic cases, due to the much larger contribution of the bow shock. We also find that the energy dissipation at the bow shock is independent of the angle between the planet's magnetic dipole and the incident stellar wind flow. If Prox b is subject to extreme space weather conditions, the radio emission is more than two orders of magnitude larger than under calm space weather conditions. This result yields expectations for a direct detection--from Earth--in radio of giant planets in close-in orbits.
format Preprint
id arxiv_https___arxiv_org_abs_2405_19116
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle MHD simulations of the space weather in Proxima b: Habitability conditions and radio emission
Peña-Moñino, Luis
Pérez-Torres, Miguel
Varela, Jacobo
Zarka, Philippe
Earth and Planetary Astrophysics
The habitability of exoplanets hosted by M-dwarf stars dramatically depends on their space weather. We present 3D magneto-hydrodynamic simulations to characterise the magneto-plasma environment and thus the habitability of the Earth-like planet Proxima b when it is subject to both calm and extreme (CME-like) space weather conditions. We study the role of the stellar wind and planetary magnetic field, and determine the radio emission arising from the interaction between the stellar wind of Proxima and the magnetosphere of its planet Proxima b. We find that if Prox b has a magnetic field similar to that of the Earth ($B_{\rm p} = B_\oplus \approx 0.32$ G) or larger, the magnetopause standoff distance is large enough to shield the surface from the stellar wind for essentially any planetary tilt but the most extreme values (close to $90^{\circ} $), under a calm space weather. Even if Proxima b is subject to more extreme space weather conditions, the planet is well shielded by an Earth-like magnetosphere ($B_{\rm p} \approx B_\oplus$; $ \approx 23.5^{\circ}$), or if it has tilt smaller than that of the Earth. For calm space weather conditions, the radio emission caused by the day-side reconnection regions can be as high as 7$\times10^{19}$ erg s$^{-1}$ in the super-Alfvénic regime, and is on average almost an order of magnitude larger than the radio emission in the sub-Alfvénic cases, due to the much larger contribution of the bow shock. We also find that the energy dissipation at the bow shock is independent of the angle between the planet's magnetic dipole and the incident stellar wind flow. If Prox b is subject to extreme space weather conditions, the radio emission is more than two orders of magnitude larger than under calm space weather conditions. This result yields expectations for a direct detection--from Earth--in radio of giant planets in close-in orbits.
title MHD simulations of the space weather in Proxima b: Habitability conditions and radio emission
topic Earth and Planetary Astrophysics
url https://arxiv.org/abs/2405.19116