Spacesuit Radiation Shield Design Methods

Wilson, John W.; Anderson, Brooke; Cucinotta, Francis A.; Ware, J.; Zeitlin, C.

doi:10.4271/2006-01-2110

Cited by 18 publications

(10 citation statements)

References 16 publications

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“…It was previously estimated that, during a journey to Mars, every cell in the body will be hit by a proton once every 3 days, and by a HZE ion approximately once a month [1]. Relating to SPEs, various organ dose rates ranging from 0 to 1 Gy/h [2] and doses ranging from 0 to 1 Gy [3] have been estimated. Hence, exposure to radiation during large SPEs can be life threatening.…”

Section: Introductionmentioning

confidence: 99%

Effects of 100 MeV protons delivered at 0.5 or 1 cGy/min on the in vivo induction of early and delayed chromosomal damage

Rithidech¹,

Honikel²,

Reungpatthanaphong³

et al. 2013

Mutation Research/Genetic Toxicology and Environmental Mutagene

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Section: Introductionmentioning

confidence: 99%

Effects of 100 MeV protons delivered at 0.5 or 1 cGy/min on the in vivo induction of early and delayed chromosomal damage

Rithidech¹,

Honikel²,

Reungpatthanaphong³

et al. 2013

Mutation Research/Genetic Toxicology and Environmental Mutagene

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“…In this case, the net slopes are plotted; i.e., slopes measured with radiation source minus slopes measured without the radiation source. The results demonstrate (1) a linear response from ambient GCR levels to the much higher dose rates possible from a large SPE, likely less than 100 mGy h −1 during EVA ( Wilson et al 2006 ) and much less inside a spaceship or a shielded planetary habitat; and (2) a reproducible response as observed for measurements made on different dates using two different gamma-ray sources. It is noted that a linear response was also observed for 241 AmBe neutrons tested over a similar range of slopes (from 0.0125 to 1.278 V s −1 ) at TAMU (data not shown).…”

Section: Testing and Validationmentioning

confidence: 63%

Compact Tissue-equivalent Proportional Counter for Deep Space Human Missions

et al. 2015

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Effects on human health from the complex radiation environment in deep space have not been measured and can only be simulated here on Earth using experimental systems and beams of radiations produced by accelerators, usually one beam at a time. This makes it particularly important to develop instruments that can be used on deep-space missions to measure quantities that are known to be relatable to the biological effectiveness of space radiation. Tissue-equivalent proportional counters (TEPCs) are such instruments. Unfortunately, present TEPCs are too large and power intensive to be used beyond low Earth orbit (LEO). Here, the authors describe a prototype of a compact TEPC designed for deep space applications with the capability to detect both ambient galactic cosmic rays and intense solar particle event radiation. The device employs an approach that permits real-time determination of (and thus quality factor) using a single detector. This was accomplished by assigning sequential sampling intervals as detectors “1” and “2” and requiring the intervals to be brief compared to the change in dose rate. Tests with γ rays show that the prototype instrument maintains linear response over the wide dose-rate range expected in space with an accuracy of better than 5% for dose rates above 3 mGy h−1. Measurements of for 200 MeV n−1 carbon ions were better than 10%. Limited tests with fission spectrum neutrons show absorbed dose-rate accuracy better than 15%.

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“…Although protons from SPEs are of much lower energy than those from GCR (and therefore can be more readily shielded), they pose an acute health risk for astronauts who are exposed during extravehicular activity (EVA). For example, if an astronaut were participating in an EVA on the Moon during the August 1972 SPE and received the full radiation from that event, the doses are calculated to be 40 Sv to the skin, 5 Sv to the yellow marrow, and 1.7 Sv to the red marrow (11). These doses would have greatly exceeded the current 30-day dose limits established for LEO of 1.5 Sv for skin and 0.25 Sv for marrow.…”

Section: The Space Radiation Environmentmentioning

confidence: 95%

“…In contrast, solar protons typically penetrate less than about 10 cm in water, and the vast majority penetrate less than 1 cm in water, barely enough to penetrate a lunar extravehicular activity (EVA) spacesuit (11). In addition to their differences in penetration power, the high-energy particles from GCR produce more secondary radiation via spallation reactions in materials.…”

Section: The Space Radiation Environmentmentioning

confidence: 99%