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  • We've added a lot to the classic picture of Mars in the last few years,

  • especially where water is concerned.

  • Between the pretty strong evidence of salty liquid water scattered across the surface,

  • not to mention the giant lake that might be hidden deep under the south pole,

  • it seems like there's a surprising amount of liquid water over there.

  • And in a paper published this week in Nature Geoscience,

  • researchers found that all this water we've been finding might actually contain enough oxygen

  • for certain forms of life to survive there.

  • Not just simple unicellular microbes, either.

  • In some places, there might even be enough oxygen for more complex life to survive.

  • So water is super important to the search for life on other worlds,

  • because as far as we know, life can't survive without it.

  • But of course, there's a big difference between figuring out whether life could survive on Mars

  • and actually finding life there.

  • And even with the evidence of liquid water, we're still working on that first one.

  • The main problem is that the water on Mars is full of a type of salt called perchlorates,

  • which happen to be pretty toxic to life as we know it.

  • But we know that life can adapt to all kinds of extreme conditions.

  • And when we talked to Vlada Stamenković, one of the authors on the new paper,

  • he noted in a place like Mars where there are perchlorates everywhere,

  • adapting to them might just be normal.

  • Still, when scientists talk about life surviving on Mars,

  • they're pretty much always referring to anaerobic life,

  • simple, unicellular life that doesn't need oxygen to survive.

  • More complex, aerobic life does require oxygen, and since there's not much of it on Mars,

  • most researchers assumed aerobic life wouldn't be able to survive there.

  • At least, until now.

  • Other recent studies have found

  • that aerobic life doesn't need quite as much dissolved oxygen to survive in water as we used to think,

  • only 0.032 parts per billion for single-celled microbes, which isnot a lot.

  • For comparison, oceans on Earth have about 200 thousand times that.

  • So the authors of this week's paper wanted to see if the oxygen content of Martian brines

  • would be enough to support aerobic life.

  • When they put together a model of how oxygen would dissolve in the brine based on the conditions on Mars,

  • they found that there were large areas of the planet

  • where the brine would have enough oxygen to support aerobic life.

  • And on about 7% of the surface, the model showed that there might even be enough oxygen

  • to support more complex, multicellular life, like sponges,

  • which need about 2000 times as much as single-celled aerobic life.

  • The researchers focused on the small brine deposits close to the Martian surface,

  • not the giant lake we think might exist about a kilometer and a half below the planet's south pole.

  • But they said that according to their results, the lake would probably have lots of dissolved oxygen, too,

  • as long as it has a reliable source of the stuff, like from the atmosphere

  • or from radiation breaking down water molecules.

  • Obviously, none of this means there is aerobic life on Mars, or that life exists there at all.

  • But Stamenković also pointed out that oxygen was a huge factor in the evolution of complex life on Earth.

  • So finding enough oxygen to support aerobic life right next door

  • opens up a lot of new possibilities in the search for life on Mars, and maybe on other worlds, too.

  • Meanwhile, NASA's InSight lander is on its way to Mars, set to touch down in late November.

  • It's not designed to study places where we think life might be able to survive,

  • since it's so hard to make sure we don't contaminate those places with microbial hitchhikers from Earth.

  • Instead, InSight is going to study the planet's interior to learn more about how rocky planets formed in the Solar System.

  • And last week, NASA released a video with more details about how exactly that will work.

  • It involvesthe claw...

  • Did I do a good job of that?

  • Seriously, though.

  • Since InSight's mission is to study the Martian interior, which we've never properly done before,

  • its scientific instruments need to be in direct contact with the surface.

  • So the lander's robotic arm has a claw attached to the end that it will use to pick up those instruments

  • and place them on the ground.

  • In other words, the highly-sophisticated robotic lander we're sending to another planet is

  • basically a glorified claw machine.

  • Unlike the machines you dump money into at the arcade, though,

  • the lander's mechanism is designed to actually pick things up.

  • The mission team considered a few other options, but there were problems with all of them.

  • A magnet, for example, might not work if too much dust got in the way.

  • It's actually a pretty cool bit of engineering, the mechanism opens up by heating up wax,

  • which then expands, putting pressure on a rod that opens the claw.

  • Then you just lower the open claw onto whatever instrument you want to move.

  • They all have hooks for the claw to grab onto.

  • When the wax cools, a spring pushes the rod back into place, closing the claw.

  • And once it's in place, it will stay closed even with the instrument pulling down on it,

  • unlike the claws in arcade machines, which are designed to open when something pulls down on them.

  • So if InSight happens to find any little three-eyed green aliens waiting for it on Mars,

  • they won't stand a chance.

  • Thanks for watching this episode of SciShow Space News!

  • And thanks especially to our Patreon President of Space SR Foxley

  • and our community on Patreon for supporting what we do.

  • You might have seen our livestream extravaganza earlier this week, where we tested some fun experiments,

  • did a live quiz show, and tried very hard to blow up a pumpkin.

  • But most importantly, we got to connect with people who share our passion

  • for spreading scientific knowledge to anyone who wants to learn.

  • We wouldn't be able to do this without your help.

  • If you're not yet a patron and want to know more, just check out patreon.com/scishow.

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