SA43B-2363
Time-dependent radiation dose estimations during interplanetary space flights

Thursday, 17 December 2015
Poster Hall (Moscone South)
Mikhail Igorevich Dobynde, Skolkovo Institute of Science and Technology, Skolkovo, Russia
Abstract:
Time-dependent radiation dose estimations during interplanetary space flights

 1,2Dobynde M.I., 2,3Drozdov A.Y., 2,4Shprits Y.Y.

1Skolkovo institute of science and technology, Moscow, Russia

2University of California Los Angeles, Los Angeles, USA

3Lomonosov Moscow State University Skobeltsyn Institute of Nuclear Physics, Moscow, Russia

4Massachusetts Institute of Technology, Cambridge, USA

Space radiation is the main restriction for long-term interplanetary space missions. It induces degradation of external components and propagates inside providing damage to internal environment. Space radiation particles and induced secondary particle showers can lead to variety of damage to astronauts in short- and long- term perspective. Contribution of two main sources of space radiation- Sun and out-of-heliosphere space varies in time in opposite phase due to the solar activity state.

Currently the only habituated mission is the international interplanetary station that flights on the low Earth orbit. Besides station shell astronauts are protected with the Earth magnetosphere- a natural shield that prevents significant damage for all humanity. Current progress in space exploration tends to lead humanity out of magnetosphere bounds. With the current study we make estimations of spacecraft parameters and astronauts damage for long-term interplanetary flights.

Applying time dependent model of GCR spectra and data on SEP spectra we show the time dependence of the radiation in a human phantom inside the shielding capsule. We pay attention to the shielding capsule design, looking for an optimal geometry parameters and materials. Different types of particles affect differently on the human providing more or less harm to the tissues. Incident particles provide a large amount of secondary particles while propagating through the shielding capsule. We make an attempt to find an optimal combination of shielding capsule parameters, namely material and thickness, that will effectively decrease the incident particle energy, at the same time minimizing flow of secondary induced particles and minimizing most harmful particle types flows.