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We advocate a low-cost strategy for long-duration research into the ‘milligravity’ environment of asteroids, comets and small moons, where surface gravity is a vector field typically less than 1/1000 the gravity of Earth. Unlike the microgravity environment of space, there

We advocate a low-cost strategy for long-duration research into the ‘milligravity’ environment of asteroids, comets and small moons, where surface gravity is a vector field typically less than 1/1000 the gravity of Earth. Unlike the microgravity environment of space, there is a directionality that gives rise, over time, to strangely familiar geologic textures and landforms. In addition to advancing planetary science, and furthering technologies for hazardous asteroid mitigation and in situ resource utilization, simplified access to long-duration milligravity offers significant potential for advancing human spaceflight, biomedicine and manufacturing. We show that a commodity 3U (10 × 10 × 34 cm3) cubesat containing a laboratory of loose materials can be spun to 1 r.p.m. = 2π/60 s-1 on its long axis, creating a centrifugal force equivalent to the surface gravity of a kilometer-sized asteroid. We describe the first flight demonstration, where small meteorite fragments will pile up to create a patch of real regolith under realistic asteroid conditions, paving the way for subsequent missions where landing and mobility technology can be flight-proven in the operational environment, in low-Earth orbit. The 3U design can be adapted for use onboard the International Space Station to allow for variable gravity experiments under ambient temperature and pressure for a broader range of experiments.

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    Title
    • A Cubesat Centrifuge for Long Duration Milligravity Research
    Date Created
    2017-06-05
    Resource Type
  • Text
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    Identifier
    • Digital object identifier: 10.1038/s41526-017-0021-0
    • Identifier Type
      International standard serial number
      Identifier Value
      2373-8065
    Note
    • The final version of this article, as published in Npj Microgravity, can be viewed online at: https://www.nature.com/articles/s41526-017-0021-0

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    This is a suggested citation. Consult the appropriate style guide for specific citation guidelines.

    Asphaug, E., Thangavelautham, J., Klesh, A., Chandra, A., Nallapu, R., Raura, L., . . . Schwartz, S. (2017). A cubesat centrifuge for long duration milligravity research. Npj Microgravity, 3(1). doi:10.1038/s41526-017-0021-0

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