The Human Energetic Radiation Assessment (HERA) Network

Paper number

IAC-13,A1,4,6,x19298

Author

Dr. Ralph L. McNutt, Jr., Johns Hopkins University Applied Physics Laboratory, United States

Coauthor

Prof. Stanislav Barabash, Institutet för Rymdfysik (Swedish Institute for Space Physics), Sweden

Coauthor

Dr. Pontus Brandt, Johns Hopkins University Applied Physics Laboraory, United States

Coauthor

Dr. Christina Cohen, California Institute of Technology, United States

Coauthor

Dr. Robert Decker, United States

Coauthor

Dr. Carolyn Ernst, The Johns Hopkins University Applied Physics Laboratory, United States

Coauthor

Dr. Nicola Fox, The Johns Hopkins University Applied Physics Laboratory, United States

Coauthor

Dr. Yoshifumi Futaana, Institutet för Rymdfysik (Swedish Institute for Space Physics), Sweden

Coauthor

Dr. Sanjoy Ghosh, The Johns Hopkins University Applied Physics Laboratory, United States

Coauthor

Dr. Dennis Haggerty, The Johns Hopkins University Applied Physics Laboratory, United States

Coauthor

Dr. Dana Hurley, The Johns Hopkins University Applied Physics Laboratory, United States

Coauthor

Dr. David Lario, The Johns Hopkins University Applied Physics Laboratory, United States

Coauthor

Dr. David Lawrence, The Johns Hopkins University Applied Physics Laboratory, United States

Coauthor

Dr. John Lyon, Dartmouth College, United States

Coauthor

Dr. Glenn Mason, The Johns Hopkins University Applied Physics Laboratory, United States

Coauthor

Mr. James McAdams, JHU Applied Physics Laboratory, United States

Coauthor

Dr. Viacheslav Merkin, The Johns Hopkins University Applied Physics Laboratory, United States

Coauthor

Dr. Richard Mewaldt, California Institute of Technology, United States

Coauthor

Dr. Christopher Paranicas, The Johns Hopkins University Applied Physics Laboratory, United States

Coauthor

Dr. Thomas Prettyman, Planetary Science Institute, United States

Coauthor

Dr. NourEddine Raouafi, The Johns Hopkins University Applied Physics Laboratory, United States

Coauthor

Dr. Edmond Roelof, The Johns Hopkins University Applied Physics Laboratory, United States

Coauthor

Dr. Mark Wiedenbeck, Jet Propulsion Laboratory - California Institute of Technology, United States

Coauthor

Dr. Michael Wiltberger, National Center for Atmospheric Research – High Altitude Observatory, United States

Year

2013

Abstract

The hazards of the space radiation environment have been known from the early days of space exploration. What are less well appreciated are the potential cumulative effects from both the space and target-induced environments on human crews. The Sun is the ultimate source of these effects whether via the modulation of galactic cosmic rays (GCRs) entering the heliosphere from interstellar space (controlling “space climate”) or from the direct injection of solar energetic particles (SEPs) from the Sun itself (a factor in shorter-term “space weather”). This combination of charged particles leads to the production of secondary particles at the surfaces of solid bodies with no atmospheres, such as the Moon, near-Earth asteroids, and the moons of Mars Phobos and Deimos, while also offering the hazard of highly-charged nuclei, such as fully-ionized iron atoms, which can cause significant levels of radiation deposition in materials encountered. While understood qualitatively, the quantitative physics of the transport of GCRs, and especially SEPs, in the inner solar system remains poorly understood. The fluxes of GCRs, which vary by small amounts over the 11-year solar cycle, have been well characterized, but the inability to shield easily against these very-high-energy particles for long space voyages makes them important at potential human destinations, as the induced particle and neutron environments can either enhance or reduce the radiation dose which would be accrued otherwise in deep space. The SEPs are less energetic but exhibit more rapid variations and can provide lethal radiation doses to unprotected human crews. Hence, a robust predictive capacity is needed, combined with a system-wide alert system, along with a good knowledge of the secondary environment produced by these particles at the surfaces of airless bodies, to ensure crewed mission success on deep-space missions. The Human Energetic Radiation Assessment (HERA) network is an effort to provide an appropriate, quantitative assessment and predictive capability for energetic particle events in the region of the inner heliosphere targeted for human exploration (~1 to ~2 AU from the Sun). By drawing upon the GCR and SEP records available from satellites over the last several solar cycles, along with data and modeling from ongoing missions, predictive capabilities can be developed both for the purposes of providing operational and engineering requirements for human crews for long-term stays at the Moon and to near-Earth asteroids and the moons of Mars as well as for providing input to long-term space-weathering of these airless bodies.

Abstract document

IAC-13,A1,4,6,x19298.brief.pdf

Manuscript document

IAC-13,A1,4,6,x19298.pdf (🔒 authorized access only).

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