{"id":33545,"date":"2022-07-20T00:00:00","date_gmt":"2022-07-20T00:00:00","guid":{"rendered":"https:\/\/c01.purpledshub.com\/bbcskyatnight\/?post_type=purple_issue&p=33545"},"modified":"2022-07-21T14:11:24","modified_gmt":"2022-07-21T14:11:24","slug":"cutting-edge-how-to-hide-from-radiation-on-mars","status":"publish","type":"post","link":"https:\/\/c01.purpledshub.com\/bbcskyatnight\/2022\/07\/20\/cutting-edge-how-to-hide-from-radiation-on-mars\/","title":{"rendered":"Cutting edge: How to hide from radiation on Mars"},"content":{"rendered":"\n
Our experts examine the hottest new research<\/p>\n\n
CUTTING EDGE<\/span><\/h2>\n\n\n\n
How to hide from radiation on Mars<\/h2>\n\n
Could Martian \u2018hobbit holes\u2019 protect future colonists from deadly radiation?<\/h4>\n\nAn artist\u2019s impression of subterranean cavern habitats on Mars <\/figcaption><\/figure>\n\n
Crewed missions into deep space will face a variety of different hazards. During the interplanetary transit on a mission to Mars, for example, the astronauts will spend around nine months in weightlessness. Without the constant loading of gravity, the body\u2019s muscles waste away and the heart weakens as it no longer has to pump blood \u2018uphill\u2019. The skeleton also becomes more fragile and long-duration astronauts can face osteoporosis, and the calcium leaching out of their bones can cause kidney stones. There\u2019s also the ever-present risk of equipment failure \u2013 problems with life support systems could spell doom for a mission.<\/span><\/p>\n\n
On top of all this is the danger presented by cosmic rays. Outer space is filled with fast-moving subatomic particles thrown out by the Sun during a coronal mass ejection or accelerated to extremely high energies by supernovae throughout the Galaxy. <\/p>\n\n
When such radiation particles strike a cell, they can cause a great deal of molecular damage, including creating mutations in the DNA and triggering cancer. <\/p>\n\n
\u201cHydrogen is the best shielding material, so tanks of rocket fuel or water could double up as radiation shields over crew quarters\u201d <\/p><\/blockquote>\n\n
There is a lot of interest in trying to understand the risks posed by cosmic radiation for astronauts on the surface of Mars and how best to protect them from this harmful bombardment. The Earth has a substantial magnetic field that deflects a lot of charged particles and our thick atmosphere absorbs most of the cosmic radiation before it can reach the surface. But Mars has neither and astronauts would be dangerously exposed. Dionysios Gakis at the University of Patras, Greece, and his colleague Dimitra Atri have been using computer models to study how best a crew might be protected. <\/p>\n\n
Going underground <\/strong><\/h4>\n\n
One method is active shielding. For example, superconducting electromagnets could be used to create a powerful magnetic field to deflect the incoming charged radiation particles away, just as Earth\u2019s field does. The problem is that such solutions can demand a lot of power to run and the technology is a long way from being fully developed. An easier alternative is passive shielding: simply placing thick bulk of shielding material between a the crew habitat and the sky. <\/p>\n\n
Gakis and Atri consider a variety of different materials. Aluminium \u2013 the metal that spacecraft are constructed from \u2013 is actually a pretty bad radiation shield. When hit by an energetic cosmic ray, its atoms can shatter and fly onwards to create even more radiation particles. <\/p>\n\n
Martian regolith suffers from the same problem, but it is abundantly available and would reduce the amount of material needing to be launched from Earth. A crew habitat could be buried beneath a 2\u20133m layer to re-absorb these secondary radiation particles. Gakis and Atri note that hydrogen is the best shielding material, as its light atoms don\u2019t create as much secondary radiation, and so tanks of rocket fuel or water placed over crew quarters could double up as effective radiation shields. Or hydrogen-rich plastics like polyethylene could be used to cement regolith grains together and improve their shielding effect. <\/p>\n\n
Personally, I love the mental image of Mars astronauts living in habitats buried within an artificial hill of Martian soil, like an extraterrestrial hobbit hole! <\/p>\n\n
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Prof Lewis Dartnell is an astrobiologist at the University of Westminster.<\/p>\n\n
Lewis Dartnell <\/strong>was reading… Modelling the Effectiveness of Radiation Shielding Materials for Astronaut Protection on Mars <\/em>by Dionysios Gakis and Dimitra Atri Read it online at: https:\/\/arxiv.org\/abs\/2205.13786<\/a><\/strong><\/p>\n\n
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