PROTECTION FROM COSMIC RADIATION IN LONG-TERM MANNED SPACEFLIGHTS

Authors

  • Marco Durante GSI Helmholtzzentrum für Schwerionenforschung GmbH, Biophysics Department

Abstract

Current space programs are shifting toward planetary exploration, and in particular towards human missions to the moon and Mars. Space radiation, comprised of energetic protons and heavy nuclei, has been shown to produce distinct biological damage compared to radiation on Earth, leading to large uncertainties in the projection of health risks. Even if uncertainties in risk assessment will be reduced in the next few years, there is little doubt that appropriate countermeasures have to be taken to reduce the exposure or the biological damage produced by cosmic radiation. In addition, it is necessary to provide effective countermeasures against solar particle events, which can produce acute effects, even life threatening, for inadequately protected crews. Unfortunately, passive (bulk) shielding is currently unable to provide adequate protection, because cosmic rays have very high energy and nuclear fragmentation in the absorbers produce light fragments. Material science could provide new materials with better shielding properties for space radiation. Active (magnetic) shielding could be an interesting alternative, pending technical improvements.

References

Casolino, M., Altamura, F., Minella, A., Minori, M., Picozza, P., Reali, E., et al. (2007). The Sileye-ALTCRISS experiment on board the International Space Station. Nuclear Instruments and Methods, A572, 235–236.

Cucinotta, F. A., & Durante, M. (2006). Cancer risk from exposure to galactic cosmic rays: implications for space exploration by human beings. The Lancet Oncology, 7, 431–435.

Cucinotta, F. A., Wilson, J. W., Williams, J. R., & Dicello, J. F. (2000). Analysis of Mir-18 results for physical and biological dosimetry: radiation shielding effectiveness in LEO. Radiation Measurements, 132, 181–191,

Durante, M., & Cucinotta, F. A. (2008). Heavy ion carcionegensis and human space exploration. Nature Reviews Cancer, 8, 465–472.

Durante, M., & Cucinotta, F.A. (2011). Physical basis of radiation protection in space travel. Reviews of Modern Physics, 83, 1245–1281.

Durante, M., Reitz, G., & Angerer, O. (2010). Space radiation research in Europe: flight experiments and ground-based studies. Radiation and Environmental Biophysics, 49, 295–302.

Guetersloh, S., Zeitlin, C., Heilbronn, L., Miller, J., Komiyama, T., Fukumura, A., et al. (2006). Polyethylene as a radiation shielding standard in simulated cosmic-ray environments. Nuclear Instruments and Methods, B252, 319–332.

Lobascio, C., Briccarello, M., Destefanis, R., Faraud, M., Gialanella, G., Grossi, G., et al. (2008). Accelerator-based tests of radiation shielding properties of materials used in human space infrastructures. Health Physics, 94, 242–247.

Maalouf, M., Durante, M., & Foray, N. (2011). Biological effects of space radiation on human cells: history, advances and outcomes. A general review. Journal of Radiation Research, 52, 126–146.

NASA, Life Sciences Division. (1998). Strategic Program Plan for Space Radiation Health Research. NASA, Washington DC.

Shavers, M. R., Zapp, N., Barber, R. E., Wilson, J. W., Qualls, G., Toupes, L., et al. (2004). Implementation of ALARA radiation protection on the ISS through polyethylene shielding augmentation of the Service Module Crew Quarters. Advances in Space Research, 34, 1333–1337.

Spillantini, P., Casolino, M., Durante, M., Mueller-Mellin, R., Reitz, G., Rossi, L., et al. (2007). Shielding from cosmic radiation for interplanetary missions: active and passive methods. Radiation Measurements, 42, 14–23.

Townsend, L. W. (2001). Overview of active methods for shielding spacecraft from energetic space radiation. Medical Physics, 17, S84–S85.

Wilson, J. W., Kim, M., Schimmerling, W., Badavi, F. F., Thibeault, S. A., Cucinotta, F. A., et al. (1995). Issues in space radiation protection: galactic cosmic rays. Health Physics, 68, 50–58.

Zeitlin, C., Guetersloh, S., Heilbronn, L., & Miller, J. (2005). Shielding and fragmentation studies. Radiation Protection Dosimetry, 116, 123–124.

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How to Cite

Durante, M. (2015). PROTECTION FROM COSMIC RADIATION IN LONG-TERM MANNED SPACEFLIGHTS. Annales Kinesiologiae, 3(1). Retrieved from https://ojs.zrs-kp.si/index.php/AK/article/view/63

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Vol. 3 No. 1 (2012)

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