Martian Soil Is Deadly. And That's Why It Might Support Life.
PBS Space Time
0:00 Thank you to The Economist for supporting PBS.
0:03 The tardigrade, the water bear,
0:05 the moss piglet, capable of surviving extreme drying,
0:08 freezing heat, radiation, the vacuum of space, maybe even asteroid impact.
0:13 And who knows, maybe some tardigrades have hitchhiked on impact ejector to Mars.
0:18 And according to a new study,
0:21 the tardigrade can survive most of the ravages of the Martian surface.
0:26 Most.
0:27 When these researchers tried adding a chemical
0:30 that is both abundant on Mars and horrifically toxic,
0:35 even the tardigrade wounds down.
0:38 So if Earth's most intrepid extreophile can't handle
0:42 the hostility of the red planet, can anything?
0:46 Well, maybe yes.
0:48 Maybe even today.
0:50 Let's see where Martian life and tardigrade astronauts may still be hiding.
1:01 We've got a couple of quick announcements before we start.
1:05 First, our eternal battle against the algorithm continues.
1:08 The best way to encourage YouTube to share our videos is to like and comment.
1:13 Doing both really makes a difference.
1:16 And if you're new here, subscribe,
1:18 hit the bell, and introduce yourself in the comments.
1:22 We're friendly.
1:23 Next up, we're excited to launch our black
1:26 hole light curves desktop and gaming mat.
1:28 This NASA inspired 32''x16'' mat accurately highlights the ways
1:32 light is warped by the gravity of a black hole.
1:35 The colors are there to help you interpret
1:37 how light paths are affected by the black hole.
1:40 There's more info on the merch store site.
1:42 Plus, our UV glow cur rotating black hole hoodies
1:46 and shirt plus the dark energy mugs are all still available.
1:50 Links in the description.
1:51 Now, on to the episode.
1:53 There are a few discoveries that will
1:55 change everything if and when we make them.
1:58 But one of the biggest is extraterrestrial life.
2:00 That's why Mars has been such a focus
2:03 for NASA's exploration of the solar system.
2:06 It was once so much like the Earth,
2:09 a real atmosphere, liquid water on the surface.
2:12 For a while, we thought we might find
2:15 primitive life cling to existence on that surface.
2:18 This was boyed by Viking Landers labeled release
2:22 experiment which tentatively detected metabolic byproducts in Martian soil.
2:26 But NASA ultimately concluded that this was due to abiotic soil chemistry.
2:30 And as the inhospitability of the Martian surface became clearer,
2:35 we downgraded our hopes.
2:37 For some time now, we've mostly been focused
2:41 on our searches for signs of past life.
2:44 And just last year, the Perseverance rover found
2:48 the most tantalizing such sign in the Jezero crater.
2:53 Mineral composition and patterning that closely resembles
2:56 the metabolic byproducts of certain Earth microbes.
2:59 And yes, we did cover that.
3:02 This potential bio signature is not conclusive, yet it's extremely exciting.
3:08 Although maybe exciting is now a relative term relative
3:12 to our diminishing hope of finding actual living life on Mars.
3:17 Now, don't get me wrong, signs of past life would be huge.
3:21 But what if we're not ready to give up?
3:24 Maybe the Jezero crater discovery should raise our hopes that somewhere
3:28 the descendants of whatever left those marks are still there,
3:33 somehow eluding our best efforts.
3:35 If so, where might they be?
3:38 There are at least a few regions on Mars that could host some sort of ecosystem.
3:43 So, let's find them.
3:45 First up, let's review why Mars used to be
3:48 an oasis and why it's now a hell hole.
3:51 A wealth of evidence from minerals that only form in water to actual dried
3:56 river and lake beds showed that liquid
3:58 water was once abundant on the Martian surface.
4:01 We also know that Mars once had a much thicker atmosphere.
4:05 Back in the day, Mars also probably had a magnetic field powered, as with Earth,
4:10 by a natural dynamo, a solid iron core spinning within a molten envelope.
4:14 But Mars is a lot smaller than Earth,
4:17 and it shed its smaller reservoir of heat more quickly.
4:21 The core solidified, the magnetic field shut off,
4:23 and the Martian atmosphere was exposed to the ablative effect of the solar wind.
4:28 As that atmosphere was sheared away, temperatures dropped,
4:31 more atmospheric gases were frozen into the surface.
4:35 As was the water.
4:36 We see that water now in Martian ice caps
4:40 and it seems occasionally leaking up from a warmer interior.
4:43 But the surface of Mars is now bone dry with an esphixxiatingly thin
4:49 atmosphere that leaves it exposed to intense
4:52 solar ultraviolet radiation and cosmic rays.
4:55 But it's even worse than that.
4:57 The exposed surface is almost all regalith.
5:01 Dust, sand, and rock fragments built up from billions
5:05 of years of meteorite impacts amplified by weathering and erosion.
5:10 And with no tectonic activity to recycle this stuff, baking under hard UV,
5:17 this regolith is photochemically altered
5:20 into various salts of chlorine and sulfur.
5:23 But without that tectonic recycling or dissolution by water,
5:28 these just build up and up and up.
5:31 Now, many of them, like the perch chlorates,
5:35 are extremely oxidizing and generally bad news
5:38 for delicate creatures made from organic molecules.
5:40 Long story short, the Martian surface sucks.
5:43 If we're searching for extent life on Mars,
5:46 we need places that are the bullseye of a habitability ven diagram.
5:51 Now, Earth boasts some species that are
5:54 tolerant of some pretty extreme circumstances.
5:56 So, we don't need to be too prescriptive here,
6:00 but there are some basic conditions that are going to be necessary for any life.
6:06 First, we need liquid water.
6:08 Now, persistent large bodies of water may not exist,
6:12 so we'll need to get creative there.
6:14 Second, we need protection from all that super
6:17 bad stuff that Mars tries to inflict on life,
6:19 like the extreme UV and the cosmic rays,
6:22 the toxic chemicals at the surface, and the extreme temperature swings.
6:26 Third, we need some source of energy.
6:29 Now, for most life on Earth, that's ultimately the sun.
6:32 But on Mars, direct exposure to the sun means exposure to all of the bad things.
6:37 So, we need to get creative here, too.
6:40 So, we want to come up with a mission
6:45 to search for where these non-negotiables actually overlap.
6:49 Water, protection, energy.
6:50 The easiest way to deal with the protection issue is to get below the surface.
6:57 And essentially, all of our possible
6:59 habitats will be subterranean or sub Martian-ian.
7:02 The less we have to dig, the sooner we'll be able to engineer our mission.
7:07 So, let's start as close to the surface as possible.
7:10 In fact, we only need to go down
7:12 a few centimeters into the Martian surface to dramatically
7:15 reduce ultraviolet radiation and a few tens
7:18 of centime to give some buffer from temperature swings.
7:22 This doesn't fix the other major problems of the surface at these depths.
7:26 It's always still below the freezing point of water and we
7:30 do need liquid water and the hazardous Martian salts remain extremely abundant.
7:34 But strangely, it turns out that those same
7:38 salts may solve the freezing problem.
7:41 Salts like perchlorates are highly oxidizing, but they're also hygroscopic,
7:46 meaning they can absorb water vapor directly from the atmosphere,
7:51 like those little packets of silica.
7:53 They're also powerful antifreeze agents,
7:56 allowing the accumulated water to remain a liquid
8:00 at temperatures as low as -70 C.
8:03 Under the right temperature and humidity conditions, these salts can deliquesce.
8:08 They form thin films of brine around
8:11 particles and within gaps of the Martian regolith.
8:15 These would likely form in the Martian night and then evaporate in the day.
8:21 So you could imagine primitive life forms that go into stasis,
8:24 perhaps even dehydrating to avoid the most
8:27 dangerous oxidation when the UV is high.
8:31 But at night they'd activate metabolizing
8:34 the chemical gradients in the Martian soil.
8:38 Are such organisms even plausible?
8:40 Well, actually, yeah.
8:41 We have things on Earth that do some of the required things.
8:47 There are various halophilic or salt loving microbes,
8:50 some of which even use perchlorates as a key part of their metabolic cycle.
8:55 For microbes in the Martian regolith,
8:58 the sun would be the ultimate source of energy.
9:01 For example, a perchlorate metabolizing critter will eat those molecules during
9:06 the night while the sun's UV will replenish them during the day.
9:10 And this points to a question that we can address without even going to Mars.
9:16 How would the hardiest Earth microbes fare in simulated Martian conditions?
9:21 It's not that hard to fake the Martian surface.
9:25 ultraviolet radiation, low pressure CO2 atmosphere,
9:28 cold and a regolith-like soil containing a variety of these salts.
9:33 Now, I already mentioned the recent tardigrade study.
9:37 These things do pretty well until perchlorates are introduced.
9:41 Then they really suffer.
9:43 And in a 2024 study, halaphilic bacteria and fungi were found
9:49 to survive pretty well in Mars-like regolith conditions,
9:53 especially at several centimeters depth.
9:56 But again, this was only until the perchlorates were introduced.
10:01 Then everything died.
10:02 So on the one hand, perchlorates may be
10:05 the best of the Martian salts at forming brines.
10:08 They suck in more water and more critically they
10:12 suppress the freezing point below the actual Martian surface temperature.
10:17 But on the other hand, they're lethal.
10:20 But don't underestimate the ingenuity of life.
10:23 Even here on Earth, we have microbes that can
10:25 use those perchlorates as a key part of their metabolism.
10:29 And on Mars, that could keep the abundance of this stuff in check.
10:34 And a study just last year found
10:37 that when you expose E.coli to increasing perchlorate concentrations,
10:41 they activate pathways for DNA repair and stress mitigation,
10:45 showing that there are biological solutions to the perchlorate toxicity.
10:49 On Mars, these perchlorates built up relatively slowly over billions of years.
10:55 And so it's plausible that micro species there
10:59 have evolved to withstand and even utilize this stuff.
11:04 So life could exist at shallow depths in the Martian
11:08 regolith even if it's a marginal and tortured existence.
11:12 But the upside is that this stuff is the easiest to search for.
11:17 And because of that our putitive life finding missions are already underway.
11:23 The Rosalyn Franklin rover.
11:24 now targeted for a 2028 launch is designed with a 2 m drill
11:29 that'll get to depths where cosmic ray
11:32 protection is good enough even for humans.
11:34 The mission is focused on looking for signs of past life,
11:38 but it's possible it'll detect biomarkers in the samples that it draws up.
11:43 It could even be that the Perseverance rover has already dug up
11:48 lifebearing material from shallower depths and packaged it for return to Earth.
11:53 Now, that sample return mission is now in question due to budgetary chaos.
11:58 But if we can get it to a proper lab
12:01 on Earth and take a look for all of the bio signatures,
12:05 even the subtlest or sparsest ones that our Mars
12:08 robots haven't been able to catch could be found.
12:12 Okay, let's see if we can find slightly more hospitable habitats.
12:17 Mars has widespread near surface ground ice, especially at high latitudes,
12:23 and orbital data suggests buried ice deposits at mid latitudes, too.
12:28 This ice would solve our protection issues.
12:32 Water in solid or liquid form is a fantastic UV and cosmic ray shield.
12:37 A meter of it is a common shielding plan for speculative human space missions.
12:42 And that same UV blocking power and separation from the atmosphere
12:47 slows the chemistry that leads to the formation of perchlorates,
12:52 which is probably a good thing.
12:55 In either phase, water has wonderful temperature stability,
12:58 which means the layer below this surface ice is
13:02 protected from the wild temperature fluctuations on the surface.
13:06 Now, solid water is not liquid water, which is what we really want.
13:11 But a 2024 NASA study found that melt
13:15 water might occasionally form beneath the ground ice.
13:18 Now, these would be thin layers of water that are warmed from below by weak
13:24 geothermal energy and from above by the UV
13:27 depleted sunlight that filters through the ice.
13:29 That liquid phase is also helped by the increased pressure from the ice layer
13:34 and perhaps some lowering of the freezing point
13:37 from a hopefully not too toxic salt concentration.
13:40 Ice also supports another intriguing possibility, radiolysis.
13:45 Ionizing radiation interacting with ice can
13:48 split water molecules producing hydrogen and oxidants.
13:51 On Earth, some deep subsurface microbes do live
13:54 off hydrogen produced by water rock interactions and radiolysis.
13:58 The Martian radiation environment while hostile at the surface
14:02 could generate chemical energy in protected icerich regions.
14:06 Now finding this sub ice life would also require a shallow drilling
14:12 mission and the Rosalyn Franklin mission
14:15 may actually find subsurface ice to investigate.
14:18 But there's also the Mars Life Explorer proposal.
14:21 If green lit, this would work towards a mid-
14:25 latatitude lander that'll aim for a location with surface ice.
14:28 It would have a 2 m drill just like
14:32 Rosal and Franklin and onboard labs to look for bio
14:35 signatures and signs of metabolism both in the bore hole
14:39 and perhaps seeping up from layers of Mars deeper down.
14:43 Another potential habitat is the Martian lava tubes.
14:48 Orbital imagery has revealed skylights,
14:51 collapsed ceilings exposing underground voids that likely
14:55 connect to lava tubes that would
14:58 have formed billions of years ago when Mars was still volcanically active.
15:03 These natural caverns could provide
15:05 excellent radiation shielding and thermal stability.
15:07 The great unknown here is whether there's water.
15:10 There could be ice deposits or brines,
15:13 perhaps even occasional water welling up from below, or they could be bone dry.
15:17 In the case of lava tubes, we're going to need to send digging or drilling
15:22 equipment much heavier than any lander or rover can handle.
15:26 Maybe we just send humans to explore the labyrinthine Martian underworld.
15:30 What could go wrong?
15:31 Anywhere close to the Martian surface,
15:34 water is probably transient and energy is limited.
15:37 That means we're unlikely to find dense, diverse, or expansive ecosystems.
15:43 More like sparse, scattered communities that may be dormant much
15:48 of the time and metabolize and grow at glacial speeds.
15:52 Just like the Earth microbes that live in sedimentary layers deep beneath
15:57 the seafloors with their cell division rates of hundreds of thousands of years.
16:02 In the case of Mars, going deeper should improve habitability.
16:06 Just meters down, there's full protection from the worst ravages of the surface.
16:12 Deeper still, temperature starts to increase.
16:15 Although the Martian interior is solid to the core,
16:18 it's still heated by the decay of radioactive material.
16:22 Same as on Earth.
16:24 Temperature rises by about 10 Kelvin per kilometer.
16:27 By the time you reach about 6 km or so,
16:30 it should be warm enough for water to be liquid, if there's any water there.
16:36 But intriguingly, recent work published in 2024
16:40 used seismic data from NASA's Insight lander to postulate that parts
16:45 of the Martian midcrust may contain gigantic aquifers.
16:50 Extensive regions of basically groundwater at depths of roughly 10 to 20 km.
16:57 The interpretation of the seismic data is still debated, but if confirmed,
17:02 this is potentially the largest region on Mars that could support an ecosystem.
17:08 The key here is that the seismic data is consistent with aquifers.
17:13 So, water saturated fractured rock as opposed
17:16 to say water carrying clays or solid rock.
17:19 Water needs to be able to flow in order to not stagnate.
17:23 Any aquous ecosystem will reach chemical and energetic
17:27 equilibrium unless there's a way to maintain chemical
17:30 gradients for energy and to replenish nutrients
17:33 and to export waste products for a deep aquifer.
17:37 That means the fractures need to connect
17:39 regions over a sufficiently large scale.
17:41 Now we absolutely do have analog life fors on Earth,
17:45 diverse bacteria and archa that thrive
17:48 in deep aquifers persisting on geochemical energy pathways.
17:52 If Mars has the right geology,
17:55 there's no reason that such a deep biosphere should not also exist there.
18:00 The main issue with this last prospect is that it's
18:03 going to be enormously difficult to test the idea.
18:06 It's going to be a long, long time before we can put together a mission
18:09 to drill several kilometers beneath the Martian surface.
18:11 Given the scale and complexity of that effort,
18:14 this might be something that also has to wait for an actual human presence.
18:18 Look, we honestly have no idea whether
18:20 there's currently life on Mars or ever was.
18:24 But the implications of extent life would be so huge that we got to look.
18:30 Maybe Earth life was actually spawned by hitchhikers on impact ejecta from Mars.
18:36 Or maybe the other way around.
18:38 Only the discovery of living life on Mars
18:41 with its intact DNA would tell us that.
18:44 And if Martian life formed independently of Earth's, well,
18:48 that tells us that life really does form easily and often,
18:53 improving the odds that we'll keep finding weird and wonderful
18:56 life forms as we expand our reach across interstellar spacetime.
19:00 Thank you to The Economist for supporting PBS.
19:04 From reporting on scientific innovation
19:06 to the shifting landscape of global politics,
19:09 The Economist's mission is to deliver
19:11 comprehensive coverage that goes beyond the headlines.
19:15 The Economist aims to make difficult topics feel approachable, not daunting,
19:19 such as a recent feature about America and China's
19:22 return to the moon and the future of lunar exploration.
19:26 A digital subscription to The Economist includes daily journalism,
19:29 plus access to their digital weekly edition,
19:32 subscriberonly podcasts and newsletters, and Insider, a new weekly video series
19:37 where senior editors debate the forces shaping geopolitics,
19:41 defense, economics, and technology.
19:43 As a viewer of PBS Spacetime,
19:46 you can get a special 35% off to enjoy The Economist.