Towards Sustainable Human Space Exploration-priorities for Radiation Research to Quantify and Mitigate Radiation Risks

Overview

Journal NPJ Microgravity

Publisher Springer Nature

Date 2023 Jan 27

PMID 36707520

Authors

Anna Fogtman

Sarah Baatout

Bjorn Baselet

Thomas Berger

Christine E Hellweg

Piers Jiggens

Chiara La Tessa

Livio Narici

Petteri Nieminen

Laure Sabatier

Giovanni Santin

Uwe Schneider

Ulrich Straube

Kevin Tabury

Walter Tinganelli

Linda Walsh

Marco Durante

Affiliations

Soon will be listed here.

Abstract

Human spaceflight is entering a new era of sustainable human space exploration. By 2030 humans will regularly fly to the Moon's orbit, return to the Moon's surface and preparations for crewed Mars missions will intensify. In planning these undertakings, several challenges will need to be addressed in order to ensure the safety of astronauts during their space travels. One of the important challenges to overcome, that could be a major showstopper of the space endeavor, is the exposure to the space radiation environment. There is an urgent need for quantifying, managing and limiting the detrimental health risks and electronics damage induced by space radiation exposure. Such risks raise key priority topics for space research programs. Risk limitation involves obtaining a better understanding of space weather phenomena and the complex radiation environment in spaceflight, as well as developing and applying accurate dosimetric instruments, understanding related short- and long-term health risks, and strategies for effective countermeasures to minimize both exposure to space radiation and the remaining effects post exposure. The ESA/SciSpacE Space Radiation White Paper identifies those topics and underlines priorities for future research and development, to enable safe human and robotic exploration of space beyond Low Earth Orbit.

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