Space invaders

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Space invaders NEXT July, a trio of spacecraft will begin their journeys to Mars. The US, Europe and China are all taking advantage of a favourable planetary alignment to launch rovers to the Red Planet and search for signs of current and past life. But what happens if a stray Earth microbe hitches a ride? That is where the principle of planetary protection comes in. The idea is to make sure that microorganisms from Earth don’t end up on other worlds – and vice versa. This is both to avoid killing off any extant life that might be on another planet and to make sure that we can still study those worlds in a relatively pristine state. “It’s really easy to find life on Mars or anywhere else,” says Catharine Conley, who was NASA’s planetary protection officer from 2006 until 2018. “Just bring it with you.” In an effort to avoid this, international planetary protection rules have been in place since the 1950s, but the rise of the private space-flight industry has prompted a rethink. If we end up in a future where SpaceX regularly lands humans on Mars, we want to avoid contamination as much as possible. At the same time, onerous regulations could restrict the growing industry. That is why, in mid-2019, NASA convened an independent board of researchers and space-flight firms to review its planetary protection policies and suggest ways to modernise the process. The board presented its final report to the international Committee on Space Research (COSPAR) last week, with a view to the protocols being adopted worldwide. SpaceX took part in the review, but didn’t respond to New Scientist’s request for comment. Some of the existing rules are a bit of a mess, says Lisa Pratt, NASA’s

20 | New Scientist | 14 December 2019

SPACEX

The rise of the private space industry may well mean allowing Earth microbes to contaminate other worlds. Is it worth the risk, asks Leah Crane

current planetary protection officer. “You have requirements that are impossible to verify or measure,” she says. “Some things are written in terms of the probability of introducing a single viable organism into a body of water, and we have no reliable or precise method to determine how many viable spores there are on a spacecraft.” The report doesn’t suggest how NASA’s protocols should change to deal with this, but it

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The number of Mars rovers due to launch in 2020

does suggest that they might not be nuanced enough. For example, when a spacecraft is en route to its destination, the cold and radiation of space will kill many onboard microorganisms. That might mean we could let spacecraft launch with more of these sorts of microorganisms than we do currently, the report says.

It also calls for a smarter consideration of a spacecraft’s destination, because different areas on the same world have different potential for biology. This principle is already in use today – for example, rovers are free to visit most of Mars, but areas that might have liquid water are deemed by COSPAR to be “special regions” that nobody can visit for fear of contamination. “When planetary protection got started, Mars was a point of light in the sky, and now it’s a real world with countless different places on it,” says Alan Stern at the Southwest Research Institute in Texas, chair of the review board. “We don’t have to protect them all equally.” (See diagram, right.) The board recommends that this system of “special regions” be expanded to other worlds besides Mars. For example, right now missions to land on Europa or Enceladus, two moons with water oceans beneath their icy shells, must have essentially no chance of bringing microorganisms to

Imagined Mars settlements may make it harder to find the planet’s native microbes

the surface. The report says that might be unnecessarily strict. “One would think that Earth life would be easily distinguishable from life that came about there,” because of the huge differences in the conditions under which it evolved, says Amanda Hendrix at the Planetary Science Institute in Arizona, who was also a member of the review board. Even if we did contaminate these worlds, the chance that it would ruin future science seems small, she says. To quantify this, the report calls for NASA to study how microbes could survive, reproduce and move around each ocean world. Understanding whether microbes could be transported by winds, ice flowing and melting, and other climate patterns will be key to deciding how different areas need to be protected, says Pratt. Those transport mechanisms could be a sticking point for planetary protection when it

Working hypothesis

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Do not land

Of course, NASA isn’t the only agency with its sights set on the moon, Mars and maybe even other destinations in the solar system. The whole thing is made more complicated – and more urgent – by the increasing accessibility of space flight. Many countries with smaller space programmes are aiming for solar system exploration, as are private companies like SpaceX, and NASA’s policies don’t necessarily apply to them. “It’s sort of an honour system,” says Hendrix. There are some international requirements through COSPAR and the Outer Space Treaty of 1967, but those requirements tend to be more lenient than NASA’s.

Expensive burden One rationale for the report was to make it easier for industry to comply with planetary protection protocols. Adhering to strict rules could make things prohibitively expensive, especially for relatively small missions. “We want to take planetary protection seriously, yet we don’t want to burden missions more than necessary,” says Hendrix. “We want to encourage

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Guidelines from the International Committee on Space Research classify space missions in one of five categories according to the risk of contaminating other worlds or Earth

Triton

I. Little to no chance of helping to understand the origins of life, so contamination poses no risk

III/IV. Significant chance of contamination from spacecraft that orbit or fly past (III) or land (IV)

II. Remote chance of Earth microbes thriving

V. Sample return missions with a risk of contaminating Earth

exploration – that’s what NASA is all about. So if it’s too burdensome, we’re not doing our job.” Conley takes a stricter approach. She describes the idea of loosening planetary protection constraints

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“We’re going to go out and explore, so we need to make sure that we don’t do something truly stupid” as “penny wise, pound foolish” and says that it risks harming future exploration for the sake of speeding it up now. “You don’t know that you’ve loosened them too much until you make a mistake,” says Conley. Such a mistake was narrowly avoided in the search for lifefriendly regions on the Martian surface, she says. Restrictions were relatively loose, because it seemed there was little chance of finding life on Mars, and they were tightened in 2003 after Mars Global Surveyor saw apparent signs of flowing liquid water. Unless everybody with space flight capabilities buys in to planetary protection, it won’t matter – one dirty spacecraft could potentially destroy any chance of finding life on an entire world. As such, further study of these alien worlds will be crucial, says Byrne. It could be time to loosen protections on the moon and Mars – explorers are raring to go – but it might be better to wait to decide how we treat complex bodies like Europa and Titan until we understand them better. “We’re going to go out and explore, so we need a framework in place to make sure that we don’t do something truly stupid,” says Byrne. Contamination will happen, but we protect the future of space exploration by doing our best to minimise it. ❚

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ALAMY STOCK PHOTO

comes to sending humans to Mars. We understand more about the Red Planet than we ever have before, but there are constant new discoveries about the surface, the subsurface and water on Mars. Sending humans there, which is one of NASA’s explicit goals, will require breaking just about every planetary protection guideline there is. “The minute we send humans to Mars, and they start pooing on Mars, forget about baking the spacecraft in cleanrooms to get rid of the microbes,” says Paul Byrne, a planetary scientist at North Carolina State University. Humans are overflowing with microbes of all sorts and it is inevitable that some will end up on the Martian surface, even though people will be wearing spacesuits. We can’t be sure that those microbes won’t spread around the Red Planet and obliterate any signs of past or present life there, but Stern says that the Martian environment is poisonous enough to Earth life that we shouldn’t worry too much. “Having humans on the surface will allow us to do science that we cannot do efficiently with robots,” he says. “It’s a little bit of downside and a lot of upside.”

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