The Supermassive Podcast - A Watery History of Mars
Episode Date: November 1, 2025Grab your space swimsuit, Izzie and Dr Becky explore Mars' wet past. When did the red planet have water? Where did it go? And were there canals on Mars? Thank you to Joe McNeil from the Natural H...istory Museum and Sian Prosser from the Royal Astronomical Society. If you like this topic, you might want to check out the NHM's new exhibition Space: Could life exist beyond Earth?Don't forget to join The Supermassive Club for ad-free listening, forum access, and behind the scenes from the team. The Supermassive Podcast is a Boffin Media production. The producers are Izzie Clarke and Richard Hollingham. Hosted on Acast. See acast.com/privacy for more information.
Transcript
Discussion (0)
We have to go to these places where we know that there is liquid water on Mars today,
and that is exclusively underground.
Does Mars have a history of glaciation?
And why the heck did they think there were canals on Mars?
Hello, welcome to the supermassive podcast from the Royal Astronomical Society,
with me, science journalist, Izzy Clark, and astrophysicist Dr. Becky Smithurst.
We thought it was about time that we did a deep dive into water on Mars.
So grab your space swimsuit, everybody.
Yeah.
So when did Mars have water?
What was a wet Mars like and where did all the water go?
We'll be speaking with Joe McNeil from the Natural History Museum
and taking a look into the Royal Astronomical Society's archives.
And obviously Dr Robert Massey,
the deputy director of the Royal Astronomical Society, is here.
So, Robert, when did Mars have water?
Well, a long, long time ago in the sense of lots of liquid water on the surface, we think.
idea is maybe 3.8 billion years ago, which if you think the solar system is four and a half
billion years old, that's a really long time ago. Mars had a much thicker atmosphere,
probably a carbon dioxide one. And that higher surface pressure means that water could be present
as liquid because if you have, say, water in a vacuum, or very low pressure, it can only either
be ice or gas. To have a liquid, you have to have a certain pressure. And that was present
apparently in early in Martian history. And it's what makes it possible on Earth today as well.
If you went very high up in the atmosphere, the earth, you can't have liquid water there either.
And we see evidence of its action on the surface, you know, evidence of giant flood shorelines,
materials cemented together and in some minerals that can only be made with the help of liquid water that the rovers are found,
the various rovers going around the surface.
And actually, of course, the only caveat on this is that it still has water today and on the surface in the form of ice.
And we sometimes see the evidence of these little transient flows, you know,
maybe something's bubbling up from underneath, but it doesn't last very long.
just because the soil is super dry, the atmosphere is too thin for it to stick around.
So it just disappears again.
But there's a lot of interest in how much that was there in the past.
So this is hopefully a great episode to talk about that.
Yeah, absolutely.
So there was a recent study on the subject.
And it comes from the Open University.
And Joe McNeil from the Natural History Museum was part of that study.
He specialises in Martian geology.
And he started by telling me what Mars was like when it had water.
Mars had water about three and a half to four billion years ago
and it would have been very, very different to the dry, cold, red desert planet that we see today
so it had a much thicker atmosphere and a climate that could support this liquid water
and this means Mars would have had an active hydrological cycle
with rain, river systems, huge lakes and maybe even an ocean in the northern hemisphere.
That's so different to how we like picture Mars now.
So how do we actually know this?
Well, I think Mars is really fascinating
because we can look at its surface using orbital spacecraft
and explore it on the ground with rovers.
And its geology and its mineralogy point to large amounts of liquid water
shaping the landscape billions of years ago.
So many of its surface features resemble things that we have on Earth.
So we have things like valley networks,
which are branching, dendritic sort of drainage patterns,
and these resemble terrestrial river systems
formed by rainfall and surface runoff, so liquid water flowing along the surface.
We also have things like outflow channels, which are these enormous tens of kilometres wide, deep
channels which are carved by catastrophic floods. This is probably from a sudden release of
groundwater, so if we have lots of water locked away in the crust, and then something causes
that to escape, it all floods out all at once. We have things like river deltas, which are these
fan-shaped sedimentary structures, which form when rivers deposit sediment into a standing
body of water, like lakes or seas. So think about the Nile Delta or the Mississippi Delta. We have
similar features on Mars. And there are also possible shorelines and tsunami deposits in the
northern hemisphere, which may point to the presence of a huge ocean in the northern hemisphere,
taking up about the top sort of third of the planet. But this is quite a contentious point.
not everyone agrees on this
and it's still an ongoing discussion.
I'll say discussion and not argument.
Okay.
And I mean, I love the idea of that though.
I don't think I've ever thought about tsunamis on Mars
until this very moment.
So that is fascinating.
And so do we know where this water would have come from?
Any initial ideas on that?
I appreciate that's probably quite a difficult thing to find out.
I mean, it was probably delivered to Mars in the same.
way that it was delivered to Earth. We think it's probably from comets very, very early on,
icy bodies delivering this water to the inner planets. We have, as well as this physical
evidence, we have telltale signs in the mineralogy as well that we can see from orbit. So we can
investigate what the composition of the surface is. And we see a lot of minerals like clays,
clay minerals, which form only through the interaction of rocks and liquid water over pretty long
periods of time. And we also have things like sulfates, which are salt deposits.
exactly like what we get in dried up lake beds on Earths.
These are really useful environmental markers to sort of investigate the water on Mars.
And so how similar would that environment have been to how we know Earth to be today?
In many ways, Mars was probably the most Earth-like planet in our solar system.
It wasn't an exact twin. There are differences.
For example, the water probably wasn't nice and warm and tropical.
When I say water, it still would have been incredibly cold.
So there would have been a lot of ice around, but it was.
would still have been a dynamic planet with an active hydrological cycle, weather, erosion,
and possibly even some areas with habitable conditions.
Do we know how much water would have been on Mars?
You know, I think when we think about Earth, we do think of it as a water planet.
There's a lot of it here.
And would that have been similar for Mars?
And I guess, would the moon still have had that interaction that we see with our waves and things like that?
I think the parallels are so interesting.
Yeah, if there was an ocean on early Mars, there probably wouldn't have been sort of tides. Mars's moons,
Vobos and Demos are simply not large enough to cause this tidal effect that we have on Earth.
Obviously, our moon relative to the size of the planet is absolutely enormous.
Mars wouldn't have had tides.
In terms of how much water Mars had, yep, people have calculated that.
In fact, there is still enough ice on Mars that we can calculate how much there would be if you melted it all right now.
If you melted everything in the polar caps, and I don't know if this takes into account,
the permafrost in the soil, but you'll end up with about 35 metres global equivalent layer.
So it's quite a substantial amount is still left, but we know a lot of it has been lost.
So it was probably, almost certainly more than that in the past.
Okay, and let's talk about losing that, because what happened to all of that water?
We don't see these huge potential oceans or these rivers on Mars anymore today.
So what happened to that water and why did it disappear?
Great question.
Mars is quite a lot smaller than the Earth
so its radius is a little bit over
3,000 kilometres
compare that with about
just over 6,000 kilometres with the earth
because of the way that spheres work
you end up with about an eighth of the volume
of Mars compared with that of Earth
and that means it just cooled down really quickly
and as its interior cooled
the convection currents in the core
stopped and these convection currents produce a global magnetic field
we still have this on Earth thankfully
and this protected the atmosphere
from the solar wind but obviously as Mars
cooled, these convection currents stopped, this magnetic field slowly went away, and without that
shield, the atmosphere was gradually stripped away into space, and as a result, the pressure
dropped, the temperature dropped, and liquid water couldn't remain stable. So it either froze into the
ground, or quite a lot of it likely escaped into space. So Mars didn't lose all of its water. It
still has quite a lot of it locked away as ice. It just became locked away as that ice as the planet,
we're underwent a gradual but irreversible change in its climate.
Yeah, so let's talk about that a bit more.
Where do we still see, I guess it's now solid water on Mars today?
And then I want to also talk about liquid water afterwards.
You know, is there any?
Do we see any signs of it?
Yeah, so there are two main places that we can find water on Mars today in its ice form.
And that is at the poles.
So Mars has two wonderful polar caps.
They are mostly made of water ice, but there's also layered carbon dioxide dry ice within that water ice and mostly on top of it.
That freezes away and resublimate seasonally.
Beneath this carbon dioxide cap, as I said, there is a sort of permanent core of water ice.
It's kilometers thick, so there's an awful lot of it.
But that's in the North Pole.
South Pole has slightly less, but that's where you find a lot of it.
Underground is the other one, so away from the poles, we've used radar to identify.
subsurface ice deposits, which is effectively where the ice has retreated into the crust and frozen
in place. So this exists as permafrost, never melting ice, and it's mostly in the mid-latitudes,
so it exists as sort of this frozen ground, which is a mix of dust and rock and ice. Yeah,
so those are the two main places we see it on Mars, at the poles, and locked away into the crust.
Okay, so you've talked about how we look for that, and I guess I want to understand what
does this mean for that all
important question on life
on Mars? You know, how
key is water for that
and can it tell us anything
about that possibility of life on Mars?
When we think about
life on Mars, we can really
define it into past life on Mars
and present life on Mars.
With past life on Mars, we tend to go to these
places that have this geological
evidence that there was lots of liquid water
here in the past. The next
rover that we're going to send to Mars is Rosalie.
Franklin, which is going to be doing something no rover has ever done before. It has a two-meter-long
drill on its front, and it's going to be drilling down into the subsurface, which is probably
where these signs of past or present life are more likely to be better preserved away from
the Martian surface environment. We can also think about life on Mars today, and so we have to go
to these places where we know that there is liquid water on Mars today, and that is exclusively
underground as these icy, briny lakes underneath the polar caps. We've used radar to interrogate
the polar cap and we found lakes of probably very, very salty hypersaline water. So we need to think
about what kind of life might be able to exist there. It would be bacterial. What kind of
places on earth might we see these high altitude lakes, sort of hypersaline places on earth, basically.
We've done the present. So let's look to the future. Why is,
Is it so important for a Mars mission that there is accessible water on Mars?
From a human exploration point of view, water's vital.
It will be the main sort of defining aspect of where we send people and when we eventually go to Mars.
So obviously, people need water to drink, to grow food, we will need water.
But there's also things like getting oxygen.
We can split water into hydrogen and oxygen.
We need oxygen to breathe.
That also has the side effect of producing hydrogen.
Hydrogen and oxygen can be used together for rocket fuel.
We can't take all of our fuel with us to Mars.
It's far too heavy, so we're going to have to make it there.
So really, when we send people to Mars,
it won't be to the most geologically or scientifically interesting places first.
It'll go to the safest place that has the correct resources.
And these will be the places that we are targeting,
where the subsurface ice is within a couple of metres of the surface.
So it's got to be very, very shallow ice.
Thank you to Joe McNeil from the Natural History Museum.
Now, we've actually had some listener questions.
I know we normally do that later,
but I thought they would be better placed here.
So Becky, Nuba on Instagram asks,
does Mars have a history of glaciation?
Good question.
It's not just a history.
It's actually that Mars has current glaciers as well.
So they're not planet-wide today like they probably used to be
when there was much more water on Mars in the past.
They're only on the poles that we've.
find them today, which we know have, you know, visible ice that you can see sort of
in imagery as well. And if you look at some of the imagery that's been taken of the current
Martian glaciers from satellites in orbit, right, they're just incredible, right? We see
all the features that you recognize from glasses on Earth, right, with the flows of the ice
and these deep grooves on the surface. And you see them even spreading out as they, you know,
sort of exit valleys and out into planes as well. Now, it is worth stating that like on Earth,
the glasses on Mars are not made of pure ice, right? There's a lot of rock in them as well
that's getting moved with the ice flows through all the sort of seasonal melting and freezing
cycles that you had. And the latest study that I could find put them around about 80% ice,
people reckon, 20% rock. So just to give people like an idea of what we're talking about
here. And it is water ice as well. It's not carbon dioxide ice, for example,
although it is thought that is possible
to maybe get like a pure carbon dioxide ice glacier on Mars
but that would be very, very rare.
In terms of the history,
which was actually the question that we've asked,
the glaciers were more widely spread
and that's thought to be because Mars's axial tilt
was actually very different.
It was much more extreme in the past.
It was more like 45 degrees tilt
rather than the 25 degrees that it is today,
which is obviously very similar to Earth's 23 degree tilt
of our axes that gives us our seasons.
So when you have that high,
of a tilt. You get much more extreme seasons. That's when the ice will build up. And so a lot of
the features that we see on the surface of Mars that appear to be glacial in origin, even on the
equator, right, have been carved out by ice, right? In the same way that, you know, like Yosemite
Valley, for example, in California, into Yosemite, that's thought to have been shaped by
glaciers in a past ice age on Earth. There's no ice there now because of the seasonal differences
are usually to get snow up high there, obviously, but not in the valley itself. Do you
I don't know. Maybe some Californians can tell me to get snow in the valley of Yosemite.
I don't actually know. But you don't have a glacier there, essentially, is what I'm trying to say.
And just to continue, like, comparisons to Earth, for anyone who's curious, because I was,
Mars is glaciers. Do not come anywhere close to the size of Earth's glaciers in terms of volume length or anything.
They're much smaller in size, which I guess you'd expect, because that's just not as much ice on Mars as there is on Earth.
Okay, amazing. Thanks, Becky. And Robert, Eric Moore asks,
could frozen water be used to replace the atmosphere on Mars,
like in the movie, Don't Real Recall.
And I'd like to say that producer Richard has also said,
just to be clear, the 1990 version is so much better than the 2012 remakes.
I don't think I've seen either, so maybe that's my homework.
Yeah, exactly.
I've fortunately seen the 19, I think the 1990s version, actually, the 2012 one.
Now I'm really struggling to remember which one is.
I believe it was the 1990s one.
I think that's the one was Schwarzenegger, isn't it?
Otherwise, my answer is going to seem nonsensical.
So, yeah, Eric, the answer is this is in the context of several decades,
probably since we discovered that Mars was not really habitable,
that it was this dry, dusty world with, you know, a very thin CO2 atmosphere, cold and so on.
There's been speculation about terraforming it, which means making it habitable like the Earth.
So in theory, we could accomplish that by filling the atmosphere with CO2,
some means of releasing that, you know, large amounts of carbon dioxide going in,
maybe have some factory producing the things we don't want to flood our own
atmosphere, methane and chlorofluorocarbons in all this stuff.
Not great things really for the earth.
But I think, as for the question of water, I think any terraformers, if they've got that
frozen water, a lot of it is way under the surface, they're going to want that for oceans
and rivers and all the rest of it rather than using that as the main atmospheric gas,
if that were even possible.
And as for the total recall thing, well, if I recall correctly, depending on which film
it is. Arnie Schwarzenegger
so Arnie sits there at the end of the film
is thrown out to some cavern with some ancient
Martian tech lying on
the surface. Spoilers for those of doing.
I know I'm sorry. I should just plug my
head now. Warn people, Robert.
Anyway, and then the atmosphere
fills with oxygen and water
in a matter of minutes, enough that
he doesn't suffocate. I think I
can safely say that's
impossible. It would take
many, many thousands of years to
make Mars look anything like the Earth. If it's
even possible. And there are some big ethical questions about it as well. You know, should you
really change a planet to be like the Earth? Which, you know, on the face of it, oh yeah,
great, another Earth. But then, you know, I don't know, I worry about, well, are we just doing
this to Mars because we're going to mess up the Earth even more? We're not going to try and maybe
fixing the Earth would be a good idea as well. And if you're an astrobiologist and you're
worried about the presence of Martian life and whether there is any, you probably don't want
to radically change the environment and kill that all off before it's discovered. So those are the
sort of bigger things. I think we've got to answer those questions before we even try. And
It's probably very, very hard and very slow, even if we get to that point.
All right.
In one of those, like, you know, just because they could doesn't mean that they should, like, you know, never stopped to think.
I personally would have to, no, let's not try and change the atmosphere with an entire planet.
And Becky, Joe mentioned tsunamis on Mars and their deposits.
Like, how would that work?
And do you know how we would see those?
Yeah, I mean, it's really interesting because on Earth, you know, tsunamis typically having when you have an earthquake, right?
So you have that shifting of the plate tectonics, like two plates shift,
and that's what sends that sort of wave out that you have the tsunami coming from.
But Mars doesn't have plate tectonics.
Like it doesn't have the sort of big continents that move and slip and, you know,
like going under and over and into each other.
So, you know, you have to kind of think, okay, well, where do tsunami deposits come from then
if there's no plate tectonics, but do you tsunamis?
And so probably people think that it actually comes from,
if you have a really large meteorite impact event,
you know, into an old northern ocean that was on Mars that could have caused a huge wave of water
and rocks to engulf the shoreline and could be one explanation for some of the features that we see
in these possible sort of shorelines on Mars. Thanks, Becky. We will tackle some more listener
questions later. As technology develops, we've been able to better understand Mars' landscape
and how it's changed, but how did the red planet look to astronomers from over 100 years ago?
Why the heck did they think there were canals on Mars?
Izzy went to the Royal Astronomical Society to find out.
I am in one of my favourite rooms in London.
It's the Library of the Royal Astronomical Society.
And yes, we're surrounded by books right now.
But we've got the addition of the bicentenary quilt.
And it's like this 100-piece patchwork of lots of different astronomical features and stars all made in fabric.
It's really beautiful and it's quite distracting.
But I'm here with Shan, the Archivist and Librarian of the Royal Astronomical Society,
to talk about what we have in the archives about water on Mars.
And, Sean, as always, you've brought quite the collection with you.
I have brought a few examples from our shelves.
These books contain some of the earliest detailed maps of Mars
that were attempted by astronomers in the late 19th century.
Let's have a look at the first book.
It's called Other Worlds Than Ours.
and it's written by Richard Proctor, who was a self-taught astronomer
and a member of the Royal Astronomical Society,
who is both a really good popular science writer
and an astronomer who was taken very seriously by his peers.
He did really original work, theories, and he was really good at mapping as well.
The first page that we're looking at here, it does say,
Other Worlds Than Ours, it's that lovely sort of typeface.
The full title is Other Worlds than Ours.
the plurality of worlds studied under the light of recent scientific researchers.
So basically, Richard Proctor has worked with astronomers selected some of the best observations for this book.
I love it. Okay, so what can we see about Mars?
Let's turn to the page on Mars. It's a chart of Mars.
We've got two circles next to each other here, and they're kind of brown circles with these green seas that are carved into them.
and very delicately drawn in, actually.
So what are we looking at here, Sean?
We're looking at basically one of the first maps of Mars
with any detail and with named features.
Richard Proctor took this from drawings by an astronomer called Dawes.
It's a multicolored lithograph print.
It's a technique that is used in scientific diagrams like this.
So, yes, you're right, Izzy.
We've got brown land masses.
intersected with pale green, basically, seas.
This is how the astronomers labelled these features
that they could see through the telescope.
The seas are named after astronomers under this system.
Remember, Richard Proctor's the first person to create this detailed map,
so he's got first dibs in his eyes on naming the features.
These are dated from 1864 and 1865.
Okay, so what are some of the names?
names that we can see here?
Well, under this system, which, you know, spoiler alert, it doesn't catch on.
He's named it after William Herschel continent, the Doors Ocean, the Lockyer Land, the Cassini land,
the Hook Sea, Laplace land.
He's kind of following the same pattern of naming craters and Mario on the moon after prominent astronomers.
And why didn't that catch on?
Another system gained greater acceptance internationally, which is a system we know today,
which is naming the features on Mars after figures in classical mythology.
I'll take some pictures and we'll put them on our Instagram because they're really beautiful.
Oh, we're taking out a big book now, so this is a bit of a much thicker book.
It's a lovely dark blue with a leather bound.
and this sort of aged pages.
We're now jumping to the year 1878.
These are observations published in this book by Skiaparelli,
who is a very famous name in the history of Mars observations.
Oh wow, so this is, this now looks far more like a graph almost.
It's rectangular rather than seeing the circles we had previously.
And again, you were just zooming into even more detailed names and features on Mars.
You can see here a different system of naming features.
They're basically named in Latin.
So we have certis major and certis minor, which are probably quite familiar features nowadays.
So basically this is the system for naming Martian features that caught on internationally.
Now, I'm really excited to get onto one of the other books that are in front of us.
to move away slightly from the mapping
and talk about a very specific feature on Mars
that one scientist in particular was convinced of.
So can we talk about this middle sort of amber-orangey book here?
Who's written it and what does it detail?
This book was written by Percival Lowell.
It was published in 1896 and it's just called Mars.
Very good. Okay.
So what was Lowell particularly looking at?
because I think this one was perhaps controversial or groundbreaking at the time?
It certainly excited a lot of interest at the time.
Let's have a look at the table of contents.
He's looking at general characteristics.
He's looking at Mars' atmosphere.
He's looking at water on Mars, canals and Oasis.
So half the book is about what he believes to be water on Mars.
He's talking about the existence of the polar cap,
which at the time was assumed to be made of waterized.
and not carbon dioxide, as we know now.
Under the section canals, he's talking about their artificiality
and their development.
Should we take a closer look?
Yes, absolutely.
So I think that's the difference.
Those maps that we were just looking at were detailing ancient places
where once upon a time there would have been water,
not saying like, yes, there's water there now.
But that is very different from what Laurel is saying,
and he is saying that actually there are current canals from his observations.
he has discovered canal systems on Mars.
So let's look at some of his comments here.
I've opened a page to plate 19 showing a whole network of nodes connected by lines.
It's stretching across the disk of Mars.
And this is the canal system that he is speculating long.
And he's not the only person to speculate about it.
And just to describe that.
image. If you imagine a sphere, that's Mars on its plate, and then you've got these
sort of bigger pools of water then connected with lines, which kind of look like these cobweb
systems, and that's what he's saying are canals. He set up his own private observatory in
the United States, and from this observatory, he observed canals. He's made a whole list of
supposed canals that he's
been able to see
183 in total
he believes exist
under the heading artificiality
he says it is patent
that here are phenomena that are passing
strange to read their riddle
we had best begin by excluding what they are
not as help
towards deciphering what they are
so you know talking about the nature of all of these
phenomena that he can observe
and there's just a lot
of discussion about
why we can see this pattern of supposed canals and what might be causing them.
In a different part of the book, he's talking about seas and the fact that he can see different
colours on the surface of Mars, you know, blue-green colours, what's it due to?
Is it, for example, caused by areas of vegetation?
Oh yeah, look at the very top of this page, it says,
but if instead of being due to water, the blue-green tint has been due to leaves and grasses.
And he talks about here about as a place where autumn came on.
Yes, it's basically not saying that the planet is blue or green.
He's just saying that he can see changes in colour as he's observing the planet throughout the seasons.
And sometimes Mars is closer to Earth than other times.
There are optimum times to observing it.
But as we will see in the next book, all of these observations, these impressions, could be seen as highly subjective.
Okay. I think that's a very polite way of saying that, Sean. So shall we look at this next book then?
Who's written it and what does it tell us? It's a lovely sort of A5, dark red leather band book.
It's got beautiful details on the front. It almost reminds me of like the storm and banding of Jupiter.
It's got lots of different colours woven into the front of it as well.
so a very unique looking book.
This is the house style for our in-house journal,
monthly notices of the Royal Astronomical Society,
which has been published for nearly 200 years now.
This happens to be a volume from 1903,
and we're going to turn the page to one article written by Edward Walter Mawnda
and his associate, J.E. Evans.
E.W. Mawnda was an astronomer.
He's teamed up with a teacher from the Royal Horndor.
hospital school in Greenwich to run some experiments on what can we really see on the surface of
Mars. Okay, that's quite an interesting pairing. What did they do to maybe have a counter-argument
to what Lowell was saying? I'll read out the introduction. The experiments described in the
following paper are undertaken in order to ascertain whether the impression of a network of fine
lines, such as forms what is now known as the canal system of Mars, could be produced upon
entirely unbiased observers without those lines having a real objective existence.
And should this prove to be the case, to find out the conditions most favourable for the
creation of such an impression.
So basically, they've taken a group of schoolboys, they've taken examples of observations of the
planet Mars, printed them out on discs of paper that are maybe three to six inches in
diameter. They've sat the boys, I'd say, you know, a certain distance from these discs, not told
the boys anything about what they're looking at, but just ask them to sketch these discs in as
much detail as possible. And they share the results of this experiment. There are some examples of
the actual drawings made by the boys. And you can see they've tried their best and sometimes
they draw canals and sometimes they don't. There's a lot of analysis and this is 1903. They are saying
that there's a great deal of subjectivity in the way that people perceive features and sometimes
canals might be suggested by the presence of dots or changes in shade in differing regions
that abut each other and it might not necessarily be canals. We can have a little
at the final paragraph of this text.
It seems a thousand pities that all those magnificent theories of human habitation, canal
construction, planetary crystallisation and the like, are based upon lines which are experiments
compel us to declare non-existent.
But with the planet Mars still left, and the imagination unimpaired, there remains hope that
a new theory no less attractive may yet be developed, and on a basis more solid than mere seeming.
Based on this study, it seemed to be an optical illusion.
Thank you to Sean Prosser.
This is the supermassive podcast from the Royal Astronomical Society
with me, astrophysicist, Dr Becky Smithhurst,
and science journalist Izzy Clark.
Has anyone seen the new live stream that's on ICVX from fake?
You're so excited about this, aren't you?
I really am, because I was having quite a boring Wednesday
and suddenly all my Instagram was saying like,
God, this has been launched.
And I know that there's been, like, NASA TV and all of these broadcasters.
But, like, just sitting down on my sofa, in my living room with a cup of tea,
just to be like, yeah, where is the International Space Station, actually?
Like, it was really relaxing.
You know, like, eight hours of a crackling fire or whatever it is?
You can put on at Christmas time for Ambion.
This is what's on in your living room for ambions, isn't it?
It absolutely is.
But those who don't know, by the way, this is, sorry, a live stream from the International Space Station,
like, looking down on the earth.
And it is just incredible to watch.
You know, you just got the view of a national in your living room.
It's perfect.
Exactly.
I haven't looked at it yet.
I do need to do this.
My social media streams were lighting up and WhatsApp groups and people saying,
oh, there's this great ITVX thing.
So you're recommending it, is it?
Yeah.
So it's kind of bizarre.
So what they've done, it's on ITVX, which is obviously an app on your TV.
And they've created space live as a channel.
So if you go into the live section of ITVX, there is now just this live stream from the
International Space Station.
as it goes over Earth
and it was lovely
because when I was watching it
it had just come over the Caribbean
and then into the corner of Brazil
and then over the oceans
and you see that moment of it
crossing over into the dark side
and the darkness of space
is insane
and I don't think I'd ever
really properly spent time
looking at it for that long
if that makes sense
you're just like you wouldn't know
that there's the earth underneath there.
It's so, so, so dark.
Yeah, because unless you happen to be going over a city or something with lights,
you just, yeah, it's just super dark.
Yeah.
It's very, very cool.
In other exciting spaces, there has been a lot of comet chat recently.
A happen there.
Yeah.
Are we excited for that?
Have we seen it?
I'm out of it, Robert.
So what do you know about Comet Lemon?
Well, I know.
So there are two.
There's Comet Swan and Comet Lemon.
And Comet Swan is a bit fainter and tougher.
They're actually not far apart in the sky.
I haven't seen either yet.
I've tried.
I did a little explain a video on it.
I went out to look last night as we do this recording and didn't see it.
I saw a cloud.
It didn't rain.
That was good.
There were the previous days.
I have been getting posts from people mostly in the north of England and Scotland with beautiful pictures of it.
I even frustratingly saw someone post from a friend of mine, Sal Russell, who was in Berkshire.
She had a lovely picture of it as well, which was coming through on this group chat.
And I haven't.
So I am going to try.
It is the, we're doing this recording on the 22nd of October.
I'm going to try tomorrow night because apparently you can see it with your eye even just about.
But perhaps it's one of those things that once you found it in an image and you know exactly where to look, you know, compared to what you've got in your foreground, like, oh, from this tree, it's just up at this angle or whatever.
Maybe it's one of those things where breaking your phone out for like a 10 second night shot might help first.
I'll take that.
I'll take my pair of binoculars.
I'll take a glimpse, you know.
I just want to go and look
instead of like sort of sitting there like last night
in a van with a friend
thinking, shall we go and look at it?
Don't know, try again.
Half an hour's gone.
Time to go out.
The glamorous life.
The glamorous life.
I was just thinking I didn't explain a video
and there's I have to go make the effort to find it.
So I just really want one clear night
when I can actually see it.
Which direction is it roughly that people should look?
Yeah, so I should explain all that.
It's over in the western sky.
So it's moving past Archerus as we're recording
this, it'll be around a bit longer if you get an app like Stellarium or something, it will show you
where it is. It's reasonably bright. You know, if you can see it with your eye, the pair of
binocas, it should be dead easy if you know where to look. So, and you're right, Becky, of course,
with a mobile phone, I'm very sure that a good mobile phone camera will pick it up to. It was
odd. It was much brighter than expected. So when it was discovered, I think it was predicted
to get to magnitude 10, which means you need a decent small telescope to see anything at all.
You know, it won't be very impressive. And then it's 100 or so or several,
hundred times brighter than that.
So it's gone through some kind of outbursts
or it's releasing a lot more material
than people imagined it would.
And the reason that it gets brighter
is because that material is lit up by the sun
and that's how we see comets.
So just maybe, just maybe, we'll see it.
Are you going to try, Izzy?
I mean, I'll try,
but out of all of the locations
that we're all crossing,
we know that I've got the worst
possible chance.
In London, built up, most light pollution.
I'm like, I can try,
but I know it's probably better for me
just to stay on Instagram
and scroll through
everyone's better photos.
No, no, you should drive out of the light
for me too, and have a go, yeah.
It's so funny though, because like you say a bit,
it wasn't predicted to get this bright.
I've basically been offline for like a month
and I've come back today and been like,
there's a comment.
There's a guy, Will Gator,
who took an amazing photo over Dartmoor,
which was incredible.
I think if you followed the UK Space Agency,
SpaceGov UK, it's on their Instagram as well.
It's a really lovely clear shot.
He had the northern lights in the same show, which I didn't see either.
The magic shot.
Which I had alerts.
Didn't see those, yeah.
I mean, no, no, you need to get out at London, Izzy.
You need to have to feel the photons coming into your eye.
Don't I know it, Robert.
Don't I know it?
Not permanently, just temporarily.
But you have been away from light pollution recently, so right?
Yes.
I was very lucky and disappeared for a month to go to Peru, as you do.
Parah.
Parah.
I went to brew for a month with friends.
And we did this four-day trek.
And on one of the first nights,
we were camping at the base of a mountain.
And it was all covered in snow and all of this.
And it got really cold.
And we were all huddled in like a sort of the,
what was the, in verticoat, you know, the dining room.
It was a tent where we ate food.
And my friend went out.
She's like, oh, I'm going to get an early night.
Walked out, came back in, was like,
oh my god have you seen the sky and so we all rushed out and i've never seen such a clear sky
like it was incredible because we were just in the middle of nowhere it the milky way just ran
straight across this valley um i'll post a picture of it because it just it was breathtaking and
hands down is the best night sky i have ever seen in my life and probably we'll see
the foreseeable yes exactly so it was it just was one of those moments and it just was one of those
It's here like, oh my gosh, this is what it's all for. Like, this is amazing. And even with just
like a quick exposure on my smartphone, it's just so much came out as well. But you could see
so much again with the naked eye. It was, it was absolutely amazing. I'm glad you got to experience
that. Yeah. The southern sky when it's super dark like that is, is a massive shock to us
northern hemispheres. Yeah. Oh, sorry, us northern hemispherians. It's just, there's just so many
stars. You're just not prepared for the number of stars that you can see. My tiny brain could
Not compute.
Right.
Shall we get back to Mars?
And we've got some more listener questions here.
So Becky, Adam has a question about living on Mars and says,
Hi, I love the pod.
If humanity is to eventually build a base on Mars, would it be closer to the poles,
i.e. closer to the water or ice, or closer to the equator?
Neither.
That's annoying thing.
There we go.
Thank you very much.
Goodbye.
Most likely it's going to be in the mid-latitudes.
so halfway between the poles and the equator.
Like, really, the poles only have the water thing going for them
in terms of pros versus cons,
where you'd want to start a base on Mars.
The equator of the two of them would win out
for the fact that you would have less extremes of temperature changes.
You would have, like, a consistent amount of sunlight as well to deal with,
like in terms of like day-to-day, or sol to solas, they call them on Mars.
You would have much more balanced seasons than the poles would,
and also you'd have the easier launch from back off Mars as well
because of this idea of if you're at the equator
you get like a boost from the planet's rotation
rather than at poles you don't have anything
you're just taking off straight upwards
it's the same reason why rockets on Earth are launched from near the equator usually
so if you're not going to put yourself near the poles or the equator on Mars
and you're going to go for a compromise and go for the mid latitudes
and you're going to want somewhere really flat for an easy landing as well
because you don't want a lot of rocks in the way they're going to knock over
what are you landing?
Yeah.
And one place that's actually been flagged for future missions by the likes of NASA and Issa is a place called Arcadia Plenicia, which I think I'm pronouncing that right, but who knows?
We'll go.
It's about 47 degrees north, so bang on mid latitudes.
And essentially, it's just this like big plane to the northwest of Olympus Mons, you know, the really massive mountain on Mars, the biggest of the solar system.
And it's formed by lava flows from that whole volcanic range, like billions of years ago.
And it ticks all the boxes of, you know, temperature seasons, sunlight, it's flat.
But it also has water going for it as well, which is very exciting.
And there's lots of evidence that there's a load of subsurface water at Arcadia,
a lot closer to the surface anyway than in other areas on Mars.
So if you can get under the surface a little bit, you can have a reliable water source
without having to schlep a lot of water to Mars.
So it helps solve the issue of what you do to help keep your astronauts.
I was supposed to say fed, but watered, I guess.
Yes. Okay. Okay. Thanks, Becky. And Robert, Huvian Keith wants to know. With toxic materials like perchlorate, which are salts in soil on Mars, what are the tech challenges of producing drinkable water on Mars?
Yeah, Keith. Not straightforward. But so various research groups have actually looked like at this. It transpires. And partly they were doing it because perchlorates are toxic. They're chemicals made with a molecule of oxygen, of chlorine.
rather than four oxygens each ionic.
They make toxic compounds.
They're not good for you.
And also they're corrosive so they can damage your equipment as well.
So there's a lot of interest in removing them.
And they're also abundant in Martian soil.
But research groups have looked at it partly to find ways to clean up water on Earth.
And I found two examples.
I mean, the straightforward thing you can do with the soil at least is to wash it out.
But of course, if you do that, you're wasting the water and it just flushes it somewhere else.
And that's the clean water you're trying to produce and use.
So another approach is to use chemistry.
And there was a group in 2021 took a fertilizer, actually, and with molybdomin and clean contaminated water that way.
Or biology and the other approach is to take where they suggested using genetically modified bacteria to do that.
So in both cases, they make much less harmful bioproducts and got clean water.
Well, in the first case, I think it was a proper experiment, but the bottles both suggest they could get clean water as a result.
So I think the answer is that it's feasible.
I don't know about doing it on a large scale and how well that would work
and you're still going to have big areas of the planet,
presumably it will have stuff in if you're just living in some small base
and trying to live off the land in your surroundings.
But it does say that it can probably be done,
but I think describing as a tech challenge is exactly right.
Yeah, I mean the idea of introducing genetically engineered bacteria into Mars is like...
It's going to say that's another level, exactly.
All of these things, you know, this is where the ethics of this stuff
are really, really important.
Do we want to take, you know, deliberately allow a genetically modified bacterium to spread across the Martian service?
Let me know.
Yeah.
Hard no from us.
Okay, good.
Well, thank you for everyone who sent in questions.
Keep them coming.
You can send them to podcast at rafatac.org.
Find us on Instagram at supermassive pod or comment on the questions thread if you're a member on the forum.
So, Robert, let's finish with some stargazing.
What can we see in the night sky?
month. Yeah. So right now, obviously we're moving in November, it's autumn. And so the autumn
stars are pretty dominant. And as the clocks have gone back by the time this goes out and the
nights are also longer, it's relatively easy to look at both evening and even the morning stars as
well. You don't have to get up stupidly early to see them. So constellations-wise, the square
of Pegasus is really high up in the south by about 9 o'clock. And it's, I think I've mentioned
this before, it's shared the constellation of Andromeda 2. It's distinguished by being a big square in
the sky with not many stars in it. And the number you can see is a good test of how dark
your sky is. So from London, realistically, quite possibly none. If you go somewhere much
darker, then you might see a few more. And if you follow the right-hand side of the square
down a long way, you come to this curiosity of the southernmost bright star, first
magnitude star visible in the UK called Fomelope. And that's just a nice thing to look out for.
We say, okay, that's the southernmost bright star I can see. But to the east of it, you've got
the famous Andromeda and the famous galaxy, which is pretty much the furthest object, the eye.
can see two and a half million light years away, and then also stars like Almac, Gamma Andromeda,
which you can just look up on a star chart, which if you look at it with a small telescope,
you see a bright yellow star on a deep blue companion. It's very, very pretty. The deep blue
companion is actually three stars, but you can't so easily see those. In the solar system,
Mercury is going to be around towards the end of November in the morning sky, and on the 24th,
it's actually near Venus, so you've got a nice pairing there. And Venus, conversely, is actually
about to disappear from view.
It's going to come right
who's going behind
or in front of the sun
but it'll be out of our
out of our skies
for a couple of months or so.
I've been up recently
where I've just seen it
in the morning
so it's sort of been
around 6 a.m.
And you just see it
just like a nice little start
to the day
just being able to start
it with Venus.
It's so pretty
and you think it'll be there
forever because it's there
for months and months
and then it goes
and it goes into the evening sky
instead but it'll be back.
It's like the only thing
that I look forward to
when the clock goes back
in October is
is those, like, catching those kind of things in the morning when you wake up?
Everything else I like about it, like, no, the Venus, catching Venus in the morning.
Venus offsets it, it does, doesn't it?
That's why we need clear skies in the morning.
Anyway, so to add a bit more, Saturn's still really good in the evening.
Those rings are still not too far away from Edge on.
It's not full Saturn yet, really.
And Jupiter starts to become easier to see as well as the month goes on.
So you start to see it earlier in the night.
You know, it's been really a morning object, and it'll be it as best in January.
And there are also two low-level meteor showers this month, the southern and northern Taurids,
which means that their meteors appear to come from Taurus, the constellation,
and they both appear to originate from the same part of the sky.
Neither of them has a lot, right, five an hour a peak, and you'll probably see two or three.
So that's not that exciting, but they do tend to be showers that produce fireballs,
which are very bright meteors, the sort of thing that gets everybody looking up excited.
So, you know, it's impossible to know when it's going to happen.
It could be absolutely any time,
but you might just have a better chance
to seeing one in the month of November
than other times.
Plus there is the peaks on the supermoon night as well
so that you've got an extra bright night.
Yeah, moon is not helpful.
Yeah, it's not something to specifically go out and look for,
but if you happen to be looking up
and you happen to see a giant bright fireball,
no, that's what it probably was
rather emailing your friendly neighbourhood of astronomers.
Oh, no, no, no.
Don't stick out for three hours just looking for these.
If you're out looking at the stars anyway,
It's a nice bonus.
I've obviously added, you know, if you see one of these
or you happen to get a picture of one,
obviously tag us on Instagram.
That's always nice.
You know, we love to see these pictures from our listeners.
Oh, lovely.
Well, thanks for that.
And I think that's it for this month.
We'll be back with a bonus episode in a few weeks' time.
And don't forget, you can join the supermassive club.
We've got the book club on there.
So everyone's sharing their stargazing photos and sharing questions as well.
So it's a lovely little place that actually...
Yeah, it's nice to see that community growing.
Yeah. So contact us if you try some astronomy at home either through the Supermassive Club or it's at Supermassive pod on Instagram or you can email any questions you might have to podcast at r.js.ac.com. And we'll try and cover them in a future episode.
But until next time, everybody, happy stargazing.