US Tests Nuclear Power System To Sustain Astronauts On Mars

Initial tests in Nevada on a compact nuclear power system designed to sustain a long-duration NASA human mission on the inhospitable surface on Mars have been successful and a full-power run is scheduled for March, officials said on Thursday. Reuters reports: National Aeronautics and Space Administration and U.S. Department of Energy officials, at a Las Vegas news conference, detailed the development of the nuclear fission system under NASA's Kilopower project. Months-long testing began in November at the energy department's Nevada National Security Site, with an eye toward providing energy for future astronaut and robotic missions in space and on the surface of Mars, the moon or other solar system destinations. A key hurdle for any long-term colony on the surface of a planet or moon, as opposed to NASA's six short lunar surface visits from 1969 to 1972, is possessing a power source strong enough to sustain a base but small and light enough to allow for transport through space. NASA's prototype power system uses a uranium-235 reactor core roughly the size of a paper towel roll. The technology could power habitats and life-support systems, enable astronauts to mine resources, recharge rovers and run processing equipment to transform resources such as ice on the planet into oxygen, water and fuel. It could also potentially augment electrically powered spacecraft propulsion systems on missions to the outer planets.

Stationary Thorium Reactor

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Turns out Mars has significant amounts of Thorium, particularly near a latitude recently found to have significant amounts of ice. The ice could be melted by and cool a thorium reactor, and electrolyzed to produce rocket fuel. There's plenty of open space on Mars to put a thorium reactor without any NIMBYs nearby worrying about strong gamma emitters or long-lived nuclear waste contaminating the environment. We could drop a few centrifuges on the planet and run them on solar for years, slowly accumulating usable fissile material before the first astronauts touch down. Of course some infrastructure to load them up would be required... but there's almost certainly going to be a need, for one reason or another, for some type of heavy backhoe drone moving soil around anyway (digging out a pit for a sub-surface habitat, getting to ice deposits, flattening landing zones, etc.)
Of course, by the time NASA gets their ass to Mars, we'll already have fusion reactors.