TY  - JOUR
A1  - Dobynde, M. I.
A1  - Shprits, Y. Y.
A1  - Drozdov, A. Y.
A1  - Hoffman, J.
A1  - Li, Ju
T1  - Beating 1 Sievert: Optimal Radiation Shielding of Astronauts on a Mission to Mars
Y1  - 2021-09-03
VL  - 19
IS  - 9
JF  - Space Weather
DO  - 10.1029/2021SW002749
PB  - 
N2  - Space radiation is one of the main concerns in planning long‐term human space missions. There are two main types of hazardous radiation: solar energetic particles (SEP) and galactic cosmic rays (GCR). The intensity and evolution of both depends on solar activity. GCR activity is most enhanced during solar minimum and lowest during solar maximum. The reduction of GCRs is alagging behind solar activity only by 6–12 month. SEP probability and intensity are maximized during solar maximum and are minimized during solar minimum. In this study, we combine models of the particle environment arising due to SEP and GCR with Monte Carlo simulations of radiation propagation inside a spacecraft and phantom. We include 28 fully ionized GCR elements from hydrogen to nickel and consider protons and nine ion species to model the SEP irradiation. Our calculations demonstrate that the optimal time for a flight to Mars would be launching the mission at solar maximum, and that the flight duration should not exceed approximately 4 years.
N2  - Plain Language Summary: Space particle radiation is one of the main concerns in planning long‐term human space missions. There are two main types of hazardous particle radiation: (a) solar energetic particles (SEP) originating from the Sun and (b) galactic cosmic rays (GCR) that come from the distant galaxies in space. Fluxes in particles of solar origin maximize during solar maximum when particles originating from the distant galaxies are more efficiently deflected from the solar system during times when the sun is active. Our calculations clearly demonstrate that the best time for launching a human space flight to Mars is during the solar maximum, as it is possible to shield from SEP particles. Our simulations show that an increase in shielding creates an increase in secondary radiation produced by the most energetic GCR, which results in a higher dose, introducing a limit to a mission duration. We estimate that a potential mission to Mars should not exceed approximately 4 years. This study shows that while space radiation imposes strict limitations and presents technological difficulties for the human mission to Mars, such a mission is still viable.
N2  - Key Points: Space missions to Mars should be scheduled to be launched during solar max. Optimal spacecraft shielding is ~30 g/cm2, which allows long‐duration flights of ~4 years. Increase of shielding thickness beyond ~30 g/cm2 results in dose increase.
UR  - http://resolver.sub.uni-goettingen.de/purl?gldocs-11858/9891
ER  -