Space may look
empty, but it contains extreme temperatures, high levels of background
radiation, micrometeoroids, and the unfiltered glare of the Sun. In
addition, materials and equipment on the outside of the International Space Station are exposed to atomic oxygen (AO)
and other charged particles as it orbits the Earth at the very edge of our
atmosphere. Only the hardiest materials, equipment, and organisms can withstand
this harsh environment, and scientists conducting research on the orbiting
laboratory have identified some of them for a variety of potential uses.
“There are ways to test the various
components of space exposure individually on the ground, but the only way to
get the combined effect of all of them at the same time is on orbit,” says Mark
Shumbera of Aegis Aerospace, which owns and operates the MISSE Flight Facility (MISSE-FF), a platform for space
exposure studies on station. “That’s important because combined effects can be
very different from individual ones.”
Missions launch about every six months to
MISSE-FF, which is sponsored by the ISS
National Lab. Experiments began when the platform was
installed in 2018 and will continue for the life of the space station, Shumbera
says. A previous MISSE facility operating from 2001 until 2016 hosted the first
station-based exposure experiments.
EXPOSE-R2 flight hardware with dried cells of Chroococcidiopsis sp. 029
mixed with Martian regolith analog to simulate Mars-like conditions for the
BIOMEX experiment on response of melanin-containing fungi to space. After
exposure, the cells were returned to Earth and rehydrated for DNA sequencing. Credits:
Roscosmos/ESA
Some of these missions help researchers understand how new technologies react to the space environment. “Before using a technology on an operational satellite or vehicle, you want some confidence that it will perform the way you think it will in the space environment,” he says.
MISSE-FF has high-definition cameras that
take periodic photos of all items on its exposure decks and sensors to record
environmental conditions such as temperature, radiation, and UV and AO
exposure. All test articles are brought back to the ground for postflight
analysis as well.
NASA scientists have flown multiple
missions on the MISSE-FF to analyze the effects of atomic oxygen and radiation
on hundreds of samples and devices.
MISSE-9, for example, assessed how polymers, composites, and
coatings handled exposure to space. For this and other MISSE missions, Kim de
Groh, senior materials research engineer at NASA’s Glenn Research Center in
Cleveland, tests two primary environmental degradation effects. The first is
how quickly a material erodes due to AO interaction. She measures loss of mass
in space-exposed materials and uses that information to compute AO erosion
yield values. These values help spacecraft designers determine whether specific
materials are suitable for use and how thick those materials need to be.
Atomic oxygen erosion of Teflon fluorinated ethylene propylene (FEP) after more than 5 years of space exposure. Credits: Kim de Groh, NASA Glenn
Materials used as spacecraft insulation can become brittle in space due to radiation and temperature cycling on orbit. This embrittlement can create cracks and cause problems such as a spacecraft component overheating. De Groh also tests the durability of different materials to find those that resist becoming brittle.
“The ideal situation is to actually expose
samples to space, to experience all the harsh environment conditions at the
same time,” de Groh says.
The EXPOSE-R-2 facility from ESA (European Space
Agency) is another platform that offers scientists the opportunity to test
samples in space. ESA investigations that have used the facility include BOSS and BIOMEX, which exposed biofilms, biomolecules,
and extremophiles to space and Mars-like conditions. Extremophiles are
organisms that can live in conditions intolerable or even lethal for most forms
of life.
Increasing autonomy is critical to future
missions that travel farther from Earth and cannot rely on resupply missions.
Microorganisms that are tolerant of extreme conditions have potential uses in
life support systems for such missions, according to Daniela Billi, a professor
in the biology department of the University of Rome Tor Vergata and an
investigator for BOSS and BIOMEX. For example, cyanobacteria can use available
resources to fix carbon (convert atmospheric carbon dioxide into carbohydrates)
and produce oxygen.
Large cracks in the Hubble Space Telescope Light Shield solar-facing multilayer insulation observed during its second servicing mission after almost 7 years in space. Credits: Townsend, High Performance Polymers
During exposure on the space station, dried Chroococcidiopsis cells received an ionizing radiation dose equivalent to a trip to Mars. Their response suggests that the bacteria could be transported to the planet and rehydrated on demand. The dried cells also were mixed with a simulant of Martian regolith or dust and received a UV dose corresponding to about 4 hours of exposure on the Martian surface.
“The aim of this study was to verify whether this cyanobacterium could repair DNA damage accumulated during travel to Mars and exposure to unattenuated Mars conditions,” says Billi.
Recently published results suggest that they can: DNA sequencing of cells rehydrated after exposure showed no increase in mutation rate compared to controls grown under Earth conditions. This result increases the potential for using this organism to employ resources available on site to support human settlements.
Another investigation using the EXPOSE-R-2 facility found signs of life in melanin-containing fungi after 16 months of exposure to space. Fungal melanin pigment seems to play a role in cellular resistance to extreme conditions, including radiation, and may have potential for use as radiation protection on future deep space missions. In the experiment, a thin layer of one strain of melanized fungus decreased radiation levels by almost 2% and potentially as much as 5%.
NASA astronauts Nick Hague and Anne McClain install the MISSE-FF inside the Japanese Kibo laboratory module’s airlock before depressurizing the unit to move the facility to the exterior of the space station. Credits: NASA
In addition to fungi, researchers used the ESA platform to expose the resting stages of some 40 species of multicellular animals and plants to space for the EXPOSE-R IBMP investigation. Results showed that many of these organisms remained viable and even completed life cycles and reproduction for several generations, suggesting future voyages to other planets could take along terrestrial life forms for use in ecological life-support systems and for creating artificial ecosystems.
As humans explore farther into space and stay there longer, tests performed on the space station’s exposure platforms help ensure the materials and systems they take along are up for the trip.
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Melissa
Gaskill
International
Space Station Program Research Office
Johnson Space Center
Source: Exposed! Space Station Tests
Organisms, Materials in Space | NASA
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