Galactic cosmic ray induced radiation dose on terrestrial exoplanets

TL;DR

This paper investigates how galactic cosmic rays contribute to radiation doses on terrestrial exoplanets, emphasizing the importance of atmospheric depth over magnetic field strength in protecting potential biospheres.

Contribution

It provides a detailed analysis of the relative impact of planetary magnetic fields and atmospheric depth on GCR-induced radiation doses, highlighting atmospheric depth as the key protective factor.

Findings

Atmospheric depth significantly reduces surface radiation dose.

Weak magnetic fields have less impact than atmospheric shielding.

High radiation doses threaten long-term biosphere sustainability.

Abstract

This past decade has seen tremendous advancements in the study of extrasolar planets. Observations are now made with increasing sophistication from both ground and space-based instruments, and exoplanets are characterized with increasing precision. There is a class of particularly interesting exoplanets, falling in the habitable zone, which is defined as the area around a star where the planet is capable of supporting liquid water on its surface. Theoretical calculations also suggest that close-in exoplanets are more likely to have weaker planetary magnetic fields, especially in case of super earths. Such exoplanets are subjected to a high flux of Galactic Cosmic Rays (GCRs) due to their weak magnetic moments. GCRs are energetic particles of astrophysical origin, which strike the planetary atmosphere and produce secondary particles, including muons, which are highly penetrating. Some of these particles reach the planetary surface and contribute to the radiation dose. Along with the magnetic field, another factor governing the radiation dose is the depth of the planetary atmosphere. The higher the depth of the planetary atmosphere, the lower the flux of secondary particles will be on the surface. If the secondary particles are energetic enough, and their flux is sufficiently high, the radiation from muons can also impact the sub-surface regions, such as in the case of Mars. If the radiation dose is too high, the chances of sustaining a long-term biosphere on the planet are very low. We explore the dependence of the GCR induced radiation dose on the strength of the planetary magnetic field and its atmospheric depth, finding that the latter is the decisive factor for the protection of a planetary biosphere.