Martian Radiation Env. Modelling Tools (QinetiQ)

1. Martian Radiation Env. Modelling Tools (QinetiQ) • It is recommended that work address three principal activities • development of tools to allow engineers to assess radiation environment for different mission scenarios • development of underlying physics to incorporate into tools • application of tools to use-case(s), e.g to demonstrate and assess performance of different habitat shielding approaches, or spacecraft/habitat “solar storm-shelter” design options and influence of particle anisotropy • A number of tools are required for future Mars mission development and operation: • An engineering model of the Martian surface and albedo radiation: • It shall be able to predict the radiation at a given time and location, and its derivative quantities i.e. primarily radiobiological dose, but also TID, NIEL, LET etc. • Requires models of the radiation for the interplanetary space, these include GCR, solar proton and X-ray, Jovian electrons. • Need model of the Martian atmosphere with greater analysis of influence of planet surface • Need a good database of the Martian surface composition • A tool to access the radiation profile for an given mission scenario: • Requires the Martian radiation model and models for interplanetary radiations. • Need Interplanetary mission trajectory generator. • Need Shielding assessment tools • Shielding assessment tools • Simple shielding tools exist, such as SSAT, MULASSIS, SHIELDOSE • Need more sophisticated 3D shielding analysis tools for detailed shielding study of spacecraft and habitat on Mars.

2. Physics developments required for the production of tools (QinetiQ) • A reference model of the GCR mode • Existing ones for the Earth environment (1AU) and they don’t agree on the short time scale (< months). • Better model for heavier ions e.g. Davis • Use existing experimental data (SREM PROBA, …) to validate the model • Models of solar energetic particle radiation • X-ray and proton: • How to scale existing engineering models such as JPL, ESP and ISO. • Model of individual event, worst case spectrum and mission-accumulated fluence, taking into account helio-radial dependence and particle anisotropy of SPE flux (use TRP IITT on Solar Energetic Particle Environment Modelling where possible) • Model of Jovain electrons • Improvement and validation of Geant4 hadron physics • The 5 - 15 GeV gap between cascade and quark gluon models • Ion physics: i) complete and validate the quark gluon model for ions; ii) improve the angular distribution of fragments in abrasion model iii) validate upper A-Z limit of binary light-ion model • Lower priority: treatment of light nuclear fragment from relativistic ED reactions, and validate fission model for 1.2GeV particle interactions. • Study the active shielding options: magnetic and electric