StarTalk Radio - Slippery Science: The Physics of Ice
Episode Date: January 6, 2023What makes ice slippery? Neil deGrasse Tyson and co-hosts Chuck Nice and Gary O’Reilly uncover the complex physics of ice and cool facts we’re still learning about it with physicist and author, La...urie Winkless. NOTE: StarTalk+ Patrons can listen to this entire episode commercial-free here: https://startalkmedia.com/show/slippery-science-the-physics-of-ice/Photo Credit: Sharon Mollerus, CC BY 2.0, via Wikimedia Commons Subscribe to SiriusXM Podcasts+ on Apple Podcasts to listen to new episodes ad-free and a whole week early.
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This is StarTalk Sports Edition.
Neil deGrasse Tyson, your personal astrophysicist and host.
Today, we're discussing the topic of ice.
Ice.
Every which way you would see it, think about it, and find it.
On Earth and in the heavens.
We're going to talk about why ice is slippery.
I bet you never really thought
about that one. Well, there's interesting surface physics related to it. We're going to talk about
ice in sports. Not all sports use ice in the same way as one another. So that's a whole other
frontier of winter sports. And we're going to talk about glaciers. What are they, how they move,
and why, and what they do to Earth's surface. All on this episode of StarTalk Sports Edition.
Welcome to StarTalk. Your place in the universe where science and pop culture collide.
StarTalk begins right now.
Jack.
Hey, Neil.
I also got Gary O'Reilly. Gary.
Hey, Neil.
How you doing, man?
I'm good. I'm good.
So, Gary, what show have you and your producers assembled today?
All right, so it's been coming and going for ages, Ice.
And right now, I guess everyone knows it's packed its bags and it's heading for the ocean.
And we'll get to that, I'm sure, later.
Humankind has learned to live with it, use it, try to understand it, and even try to have fun with it.
And I can't think of anyone better to ride a Zamboni with than our guest, Laurie Winklis.
If you don't remember, I'll explain. If you do,
then you'll know you're in for a treat. Laurie is a physicist, an astrophysicist, an author,
a science communicator, and storyteller. She's a science journalist and lecturer, and her books
include Science in the City and Sticky, the Secret Science of Surfaces. So Neil, Laurie Winklis is
back.
And that must have been the most beautiful thing anyone has ever said to anyone.
Will you ride the Zamboni with me?
I'm so flattered.
I would do anything, Gary, to have that opportunity.
I've never been on a Zamboni. It just seemed like the best thing to, you know, what can we use on ice?
A Zamboni.
I'm in. I'm in.
I'm in.
Take me in, Gary.
All right.
We'll try to make that happen.
So the only thing more unique than riding a Zamboni is being hit by one.
Or trying to run away from one while on ice.
Oh, yeah.
Yeah.
So, Laurie, I just want to lead off by asking, what makes ice slippery?
People say, well, because it gets wet and you slip on the wet ice.
But on an ice skating rink, the ice, if it's been skated on, it's kind of frosty, right, from everybody kicking up the top layer of shaved ice.
But that's slippery, too.
And no matter what I'm wearing.
So you see people at the end of a hockey game,
the coach comes out,
he's got to step lightly on the ice lest he slip.
So just wondering what's going on there.
And does it have anything to do with the sketchy character of ice?
Perhaps.
Ice cannot be trusted.
Maybe that's why it's slippery.
It's very sketchy in its character.
Yeah, exactly.
And honestly, that is true.
And that's true scientifically too, Chuck,
because ice is not always slippery.
If you get ice cold enough,
the friction that it generates is really high.
So it actually becomes a very grippy surface.
So if you're way down at like minus 100 degrees C, the friction that a skate or a shoe that would experience on that ice is extremely high.
It's as if you're walking on a very rough surface.
But as the temperature of ice increases and kind of heads towards its melting temperature.
So I'm sorry I'm speaking in centigrade, but I'm useless.
We'll forgive you.
But yes, thank you.
So yeah, it starts very high friction.
And then the friction actually gradually decreases
and it reaches a minimum at about minus seven degrees C.
And that's quite a useful temperature
because that's the type of temperature
that we would quite often interact with on an ice skating rink. And although there've been theories around
how that happens, why friction decreases gradually over that range, it wasn't really until about
2018 that researchers, I think, probably got closest to kind of nailing down the answer to
why. And it's that there is always a presence of what they call
a quasi-liquid. There's always this ultra-thin, like just a few nanometers thin layer of quasi-liquid,
which Daniel Bond, the scientist who wrote this paper in 2018, would not let me call a liquid,
a quasi-liquid that exists on ice, even at temperatures well below freezing. So ice
always has this layer on there and that
contributes to its slipperiness. Just to be clear, a nanometer is a billionth of a meter.
So we hear the word nano so often that it's almost lost its precision. Nanobox, nanodip,
it's nano. But you're using the word within its precise metric prefix way, nanometers, billionths of a meter thin, just to clarify that.
Quasi-liquid.
I mean, that's rather vague and amorphous.
Indeed.
Quasi-liquid?
I mean, come on.
Really?
Yeah.
Well, yeah, this is it. I had this argument with the scientist as well.
But his argument, and it's a reasonable one, is that if it's below freezing, it should be a solid.
So we shouldn't be calling it a liquid, right?
But what it actually is, is that on the surface of ice, you have little ice molecules, water molecules,
that are bound to all the other water molecules around it.
And normally ice is bonded to four neighbors, right?
On the surface of ice, it's bonded to three or four
because it's on the surface, there's air above it,
it's no longer surrounded by more ice.
But what these guys realized, and actually I should say,
they're brothers, the two lead scientists on this paper.
One's a chemist, one's a physicist.
Okay, that's problematic right there.
Indeed.
Hence the quasi-liquid argument, I believe.
So what they realized is that on the surface of ice at these temperatures, at this kind of minus seven degrees C, it's not just three or four bonds.
It's sometimes ice is only bonded to two
neighbors. And those doubly bonded ice molecules, they don't just kind of wiggle around on the
surface, which is what creates this quasi-liquid layer. They can actually roll around the surface
of the ice. They're very, very mobile. And it's actually those hardly bonded to their neighbors molecules of ice that cause, that create this liquidy layer that creates that slipperiness.
So, you know what we call that in just the regular world, this kind of semi-formed liquid that you're talking about?
We call it gel.
Gel, okay.
So, Laurie, the Bond brothers are doing their research in 2018 right and they have all of the technology
to do it but back in the day way back in the day michael faraday in about 1850 was coming up with
terms like re-gelation am i right and but although molecules the kind of the the theory back then wasn't popular about molecular and atoms,
all the rest of it, but he was already on it.
He totally was.
Yeah, Michael Faraday had this idea that there was some sort of liquid layer on the surface
of ice and that if you brought two ice cubes together, those liquid layers would interact
and it would allow the ice cubes to kind of freeze together.
So that's the process of regulation. But because, like you said, Gary, because this theory of atoms,
that didn't exist yet, it was kind of ignored. Faraday was kind of like, yeah, okay, you're a
great scientist, et cetera, et cetera. But that doesn't seem to make sense to us. And it was kind
of revisited again another hundred years later by a different scientist. And that was where, you know, we then had the theory of atoms and molecules. So that
started to really kind of open the floodgates, as it were, to this theory that there's some sort of
permanent liquidy layer on the surface of ice. Just to be more precise here, I think we had a
theory of atoms, but atoms were not yet demonstrated to
exist. Yes. So, because we had the periodic table of elements. Absolutely. An element,
and it would be an atom in its smallest form. So, we had some suspicions that atoms mattered,
but not in what way. And quantum physics was a distant dream, not even a dream. So, yeah. I just
want to distinguish between
what we thought might have been true
and what would later be confirmed.
That's all.
God, those guys were idiots back then.
Is there a difference between the ice that forms here on Earth
and ice that goes and forms in deep space
on comets and moons and stuff?
That's a good question.
I mean, I can only answer a tiny bit of it, but I'm sure Neil can answer way more than this.
Yeah, but wait a minute.
Before you answer that, doesn't that change based on what the ice is?
Because when we talk ice, we're talking water.
But in space, you got to have different kinds of ice other than water, right?
Yeah, good point.
But yeah, even water ice forms differently on different planets,
as far as I understand.
Oh, delicious.
Yeah.
Delicious water ice.
Water ice.
But yeah, crystalline ice is the most common form of ice on Earth.
But my understanding is that amorphous ice,
so not ice that forms these lovely crystals,
but ice that's more kind of uniform,
that is what dominates in the rest of our solar system.
But I'm sure Neil
will correct me if I'm wrong.
Oh, man, this is good stuff.
Now let's get into this.
Neil, what's up
with the ice, bro?
You know, it's a new rapper,
Amorphous Ice.
You see, that's when
it's got to be made.
Is Amorphous Ice slippery?
Oh, yeah. Does Amorphous Ice have character traitsous ice slippery? Oh, yeah.
Does amorphous ice have character traits, like slippery?
Oh, yeah.
A new superhero.
Yeah.
But wait, so I'm just astonished here, Laurie, that here it is.
We're going into the year 2023, and you're telling me that a research paper five years ago is still shedding light
on our understanding of the surface of ice.
Yeah, precisely that.
And I really love that because I think when I started to research ice, I thought, we know
all this, right?
We know it all.
Wait, Laurie, Laurie, one of your expertise is material physics, right?
So shouldn't you be embarrassed by this,
that your field didn't even know this until, you know, just before COVID?
There's so many questions to answer and only so much is able to slending.
That's my argument.
Oh, okay.
Too many surfaces, too little time.
Too little money.
Too little time, yeah.
Gary, where did I leave off with you?
Well, it was just a case of
if the ice is different in deep space
as opposed to here on Earth,
would it be, as Chuck said,
from different molecules,
not water molecules,
but other properties?
Yeah, we've got ammonia ice.
There are other things that are,
there's carbon dioxide ice,
which on Earth we call...
Lori? Dry ice? It's not dry ice.
Dry ice. Yeah.
Don't stick your tongue to that,
by the way. Do not.
Chuck speaking
from experience, it sounds like.
Whatever you do,
don't...
Whatever you do, don't stick your tongue
on dry ice.
Believe me, this thing I'm talking to you with is a prosthetic.
Your tongue?
Exactly.
So a couple more things. So it seems to me to be interesting if you had a race, let's say a quarter, a 400-meter race or a kilometer, where the beginning of the race, the whole
race is run on ice.
But at the beginning, it's like 100 below, so you get very high friction.
And so they're just running and running, but the track gets warmer and warmer until the
finish line.
And then there's some point where it's no longer high friction, it's low friction,
so they have to run differently.
And then the last 50 yards,
they just slide in.
I love it.
It's a pretty cool event.
It is also the most expensive ice rink
in the world.
Great.
It started here.
Great.
Okay.
It does take them a long time
to make ice for the Winter Olympics.
So yeah,
I don't know if they could do that gradient.
Maybe, maybe they could.
So Laurie, tell me about the attachment to other molecules.
When I think of a crystal, I think you have a molecule in its place and the crystal has
certain symmetry to it.
So I'd be looking different directions and I'd find neighbor molecules attached to me
in crystalline form.
But you tell me, as you get to the surface,
I'm missing one or more of these.
And on some level, it can actually roll around.
If I'm attached at all, how am I rolling around?
Yeah, it's a good question.
And the answer is not that straightforward
because they had to model these doubly bonded molecules.
So they haven't seen them.
They haven't actually seen what they look like.
But what they found was that as the temperature increased towards minus seven degrees C,
the mobility of these molecules in their model increased.
So it was as if they were rolling around on the surface.
Now, we haven't seen that.
So we haven't seen it experimentally.
It is a model result, but it does match very nicely with the decreasing friction that we see at the same increasing temperature.
Okay, so that's the vocabulary they have available to them to reference it that way.
Yeah.
But it's interesting.
So if a molecule only rotated a little bit, you know, moved around a little bit, and then the next one picks it up, the molecule wouldn't have to move very far to still give the impression of a very slippery surface yes seems to me precisely that and i think
it's what was really surprising to them was was just how different the mobility this movement of
these molecules just how different it was between three bonds and two bonds they really were not
expecting that it was significantly more mobile so la So, Laurie, are we now consigned
pressure melting to the bin, to the trash can, to the bin, whatever you want to call it?
Well, describe pressure melting. Pressure melting, that was my only understanding of
any of this. Now you're going to put it in a trash bin?
Yeah. I'm asking. I mean, yes, it's got to be. What's the temperature?
I mean, yes, it's got to be.
What's the temperature?
So, thank you.
It's that situation where, yes, pressure melting must still happen,
but it's not the reason when you put your foot directly onto ice that you slip.
Because there's no pressure really happening there to melt the ice. There's no high pressure like on the edge of an ice.
Yes, on the edge of a blade.
So, are we consigning that theory to,
and it's more this unstable group of molecules
that will and will not float around the surface of ice?
Pressure melting does play some sort of a limited role,
and it actually plays a role in one of the winter sports,
like curling, for example.
We're going to get to that.
But you've got to explain pressure melting. We're going to get to that.
But you got to explain pressure melting.
We're going to save that
for the second segment.
What is pressure melting?
All right.
When we come back,
Lori tells us
how you get pressure melting
with ice
on StarTalk Sports Edition
when we return. turn we're back star talk sports edition we've got our favorite ice expert in the whole world
laurie winkless coming to us from where are you Lori? I'm in Wellington in New Zealand where it is
summer. Okay sorry yeah there's summer and winter here that's evidence that the distance of earth
from the sun is not what causes seasons if you had ever wondered that it's just how we are tilted
either toward the sun or away so Lori tell us what pressure is. I think it's one of the most interesting phenomenon involving water.
And it's not other materials.
I think water is almost unique in this property.
And then we want to find out how that relates to all the sports that people know and love that take place on the ice.
Yeah, pressure melting.
You're right, Neil.
Water is a very weird molecule in some ways. So pressure melting is what happens that when you apply pressure to solid ice, what you actually do is you push the atoms in that ice closer together. Now, you think about that as making it denser. But because water is denser than ice, when ice is under pressure, it turns into, some of it turns into liquid water.
Even though the temperature is below freezing?
Even though the temperature is below freezing, yes.
Right, right.
So you would have created water in a liquid state that is stable below the freezing temperature because you put pressure on it.
Yes.
And if you remove the pressure and the temperature stays the same, usually it will freeze again.
Right.
So it does need the continuous supply application of pressure to keep that layer of water.
But that weird quasi-liquid that we talked about, that exists regardless of whether there's
pressure on the ice or not.
So is that why when you have a container in the freezer
and before the container bursts,
it's complete liquid,
but then you twist the top
and the whole thing goes and freezes up all at once.
Yeah, that's another, that's a thing called nucleation.
And it's what happens when, if you have the liquid can stay liquid, excuse me, the water
can stay liquid below freezing, but the act of kind of hitting it or, you know, banging
it in some way causes some of the water molecules, because they're cold, to line up in a line.
And then what you see is that ice just going and it forms out into the liquid.
Don't you need very pure water for that?
No, you can actually do it.
No, it doesn't need to be that pure.
You can actually do it with kind of, you know,
pretty decent bottled water
or if you have filtered water.
If you're very careful and you put it into your freezer
and leave it there for a few hours
and very carefully take it out
and then give it a smack on the countertop, you can quite often see the ice forming yeah it's pretty cool experiment
i recommend it's very cool watch ice form right in front of your eyes it's very it's very cool
lori the bond brothers and their their research in 2018 right came up with that minus seven
specific temperature.
Yeah, you can't tell me that for centuries,
ice meisters, as they're known, I believe,
weren't already well ahead of them.
Yeah, what's an ice meister?
Okay, Chuck, so to my knowledge,
and Laurie's going to either tell me I'm talking absolute rubbish or I'm right, an ice master is someone who lays the ice, they will construct a
skating rink, a track, a curling ice, whatever it is, because they're all different types of ice.
Figure skating ice is not the same as ice you play ice hockey on. It has to have different qualities.
Now, the ice masters knew this. So why didn't the Bond brothers just go and speak to an icemeister?
Well, I think they did.
But I think the other thing is, you know, there's knowing through kind of experimentation and then there's understanding from a fundamental point of view.
And you're absolutely right, Gary.
Icemeisters have known about the changing behavior of ice at different temperatures
for a very, very long time.
And it is the basis of all winter sports, really.
But it's only really now that we start to understand the very fundamental mechanism
that reflects that observation.
So you need both, I think.
But yeah, for sure.
And the ice masters I spoke to have such an incredible instinctive understanding of ice,
like some of them described being able to listen to the ice to know whether it was good
enough quality.
Ice whisperers.
Yeah.
Ice whisperers.
That's what we need.
Yes.
Oh, that's hilarious.
But Gary, this is a very common arc of discovery and understanding in science where people
just observant people notice something and then they
write it down or share the information and they might even exploit it in whatever way they need.
And then science comes later typically and figures out what's actually going on. And then when you do
that, you can usually exploit it even further, right?, Laurie, in the era of modern science,
have they improved on what the ice meisters had been doing?
I think it seems to me they could or should.
Yeah, in terms of their understanding, yes.
But the ice meisters still do what they do as they've always done.
What's helped them a bit is the ability to purify water.
So for ice makers, they really do want very, very pure water
because they want to know exactly how the ice will form
with as few kind of dirty bits in there as possible
or any other contaminants.
So that has, science has helped them hugely in that regard
because you now have technologies that allow you to filter the water.
But they still very much see it as a kind of an instinctive art, really.
And curling ice particularly because
it's different from the other ice like they are artists those ice makers they they have
they've tried different machines to create curling ice but nothing has managed to create it as
uniformly as a human uh walking up and down the ice with effectively a shower head. And that's because the machines can't listen to the ice.
Laurie, before we get on to curling,
and I do want to get on to curling
because it's a fascinating sport for physics.
And I mean, it's how many hundreds of years old and we still...
Wait, wait, Chuck, you hear what Gary said there?
It's a fascinating sport for physicists.
No, it is.
It's a fascinating sport. No, it is. It's a fascinating sport.
No, in terms of it's fascinating
and it's hundreds of years old
and we still don't know all of its secrets.
But before we go there,
please explain the impenber effect
that I believe, right?
Yes, thank you.
Suggests that hot water can freeze faster than cold water
because now I need some illumination on that.
No, that's bullshit.
I don't believe that for a minute.
Thanks, Neil.
Laurie, here's what I think
happens there.
I've seen people do this experiment.
Here's what I think happens.
They put boiling water
in an ice tray
and cold water in an ice tray
and they put them both
into the freezer.
And then the boiling water,
that ice tray freezes faster.
What I think happened there is that it evaporated water out and there was less water to freeze
by the end.
Is that not what happened there?
No, I think that's my understanding of it as well.
There's been lots of papers and lots of observations of this over the years, but yeah, I'm kind
of with you on that, Neil.
I think that's what happens.
Yeah.
In the end, it's less water to freeze.
Yeah, exactly.
So it happens quicker.
Yeah.
All right.
That makes perfect sense
because otherwise
it would have to be
some manipulation of temperature
like where you don't have
the same rate of freezing
because I don't care what you do,
you got to go from hot to cold.
Yeah.
Yeah.
You got to pass through the temperature
that the other ice cube was.
Right.
And it wasn't in the fast lanes.
Right.
So the way to do that experiment properly
is you put boiling water in a vessel that's sealed.
That way nobody can evaporate out
and then it's pure temperature.
That's why it's a bit bushy.
That's why I thought I'd tell you that.
All right.
I hide my answer.
Okay. Okay.
Okay.
So, Laurie,
so I'm at a
loss.
Why is the
ice for curling
different than
for hockey,
different than
for figure skating?
So figure skating
ice and hockey
ice and long,
like speed track
skating ice,
they're all smooth
ice.
Now, they're
different from each
other. They're at different temperatures now they're different from each other
they're at different temperatures they have different thicknesses etc etc um because each
of those sports want to do something different right like long track speed skating is all about
going as fast as you can like 50 kilometers an hour with your legs on the ice and so there you
want really hard really low friction ice so it's at the magic temperature of minus seven degrees C.
And then it gets warmer from there.
But curling ice is not smooth ice.
So curling ice, they do make a flat rink, a flat surface of ice first.
And then one of these ice meisters will walk up and down the whole length of the curling rink.
And they will use basically a showerhead which they've got
a bucket of water on their back and they spray they swing a showerhead from side to side different
little nozzle sizes on the showerhead and it creates a layer of pebbles they call them pebbles
but ice bumps all over the surface so if you look at a curling ice rink it's it's quite dull it's
not smooth and shiny like a speed skating rink. Why aren't they trying to reduce the friction? So what they're trying to do really is
if you try and curl a curling stone, so if you try and make a curling stone take that big curvy path
on smooth ice, it will not do that. Oh, you need the friction to change direction.
So the thing, Neil, don't forget the origin of curling.
It's on a frozen pond or a frozen lake.
And therefore, Mother Nature
just organically produces this pebbling,
these ice bumps, as Laurie calls them.
Yeah.
Right, right.
Nothing bumpier than a frozen lake surface.
Yeah.
I'll tell you that.
Well, yeah, so they have kind of,
if dew forms on an ice surface,
you will get these bumps so
yeah it's and like gary said it's been around curling as a sport's been around for at least
500 years and started in scotland and has kind of gone everywhere that scottish settlers have so
it's it's kind of relatively big it's not really but it's relatively big in new zealand as well
where we had a lot of scott down at the bottom of the South Island.
All right, that makes a lot of sense now.
The whole thing makes sense to me now.
Why, there's no curling in Africa?
There's no Scottish people in Africa.
I mean, yeah,
not because of the ice,
just because of the Scottish people.
It's delightful.
The teams, even like the teams,
I met some teams who play here
and they all have like these kind of woolly hats with a bobble on them, like very kind of traditional Scottish garb that they still wear and they have tartans and stuff for each of the teams.
So it's still very much seen as a Scottish sport.
Wow.
Cool.
So the Scots are actually responsible for two of the world's most boring sports.
Golf and curling.
I agree on golf.
I love curling, though.
No, I love curling, too.
So, Laurie, there's been a little bit of an argument, a spat, a tiff, call it what you like.
Those people that believe…
Dust up, yeah.
Well, yes.
Pressure warming theory, and then scratch guiding theory, and then there's the pivot slide model.
Yeah.
As to which one is the most explanatory for why a curling stone does what it does.
But before we get to that, would you explain actually what the bottom of a curling stone is like?
Because I think people have got one idea of it.
I have no idea.
There you go.
So this, Neil, is for you.
I have no idea.
Okay.
So the reason that there are so many theories about curling
is that a curling stone moves in a way that you wouldn't expect
if you were just looking at really basic physics, right?
So the base of a curling stone is not flat.
It's actually concave. So there's only
a very narrow ring. And these stones are granite. They're made from a really particular granite from
one place in Scotland. And it's this really narrow band of granite that actually touches the ice.
And then as we've established, the ice itself is pebbles. So it's kind of rough. So it's really
only touching the tops of these pebbles, right's kind of rough so it's really only touching the tops of
these pebbles right so you have this slightly odd interaction anyway you've got a rough granite
surface and a rough textured ice and if you were to say take like a beer bottle I recommend it
being empty before you do this and slide it along a table and you know it will just slide forward
if you slide it and rotate it as you release it it will just slide forward. If you slide it and rotate
it as you release it, which is what a curler will do before they release a curling stone,
the beer bottle will veer away from that straight line. It'll kind of go off to the right or the
left, depending on which direction you've rotated it. Okay. So if you rotate a beer bottle to the right as you let it go, it will curl to the left.
And this is called asymmetric friction.
So that's kind of something that we kind of know in the world of physics.
It's because of the way the bottle decelerates as it moves forward and friction is stronger
on the front than on the back of the bottle.
It's not surprising.
So yeah, so this is how a beer bottle will move, right?
But if so, you have, you curl to the right
and it will, sorry, you rotate to the right,
it'll curl to the left.
A curling stone will curl in the same direction
in which it rotates.
So from a physics point of view, that is weird, right?
If it was following this basic like asymmetric friction,
it would curl in the opposite direction to the one that it spins.
So that's why people have been like, what is going on with this weird sport?
And again, like Gary said earlier, there's a case of people understand instinctively how to rotate a stone, how to deliver a curling stone.
They understand all of this. They understand what happens when they move a stone the way they do.
understand all of this. They understand what happens when they move a stone the way they do.
But the fundamental understanding of what's happening where that kind of rough granite surface is touching the rough pebbled ice is still a little bit up for debate. Now, I'd argue that
there's probably a couple of leading theories, but probably one leading theory at the moment.
But I just love that it's still up for debate, given that this is a sport that's been around for centuries.
Well, I will tell you this, Laurie, what you have done is given the world a way to make
curling infinitely more interesting.
Thank you.
That is, put a beer bottle on top of the curling stone and have it delivered to the people at the end of the run.
All right, so, Lori, typically,
hockey is the same season as the ice capades,
the literal ice capades or whatever is that version today
that we all grew up with
going to arenas. And are you suggesting that when they do their figure skating in the ice capades,
they might change the temperature of the ice to serve their needs relative to the hockey game
that's going to play that evening? Yeah, they will do. So for figure skating,
what you want is a kind of a softer ice, to be honest, because if you think about what a figure skater is doing, they're having to kind of dig into the ice so that they can launch upwards, you know, so they actually need to get the blades warmest ice. It's like minus five degrees C, I'm sorry, minus three degrees C is figure
skating. But ice hockey needs something a bit harder because they have to, they need that
combination of grip and glide, you know, they're changing direction a lot. So ice hockey ice tends
to be about minus five degrees C. So you can switch between the two. You tend to need to flood. You tend to go, I think
from memory, I think you go ice hockey to figure skating. I think that's right. But you can kind of
add more water. You flood the ice. They literally flood it with water and let it freeze and then add
more water and let it freeze. And they can change the underlying temperature of what's underneath,
the compressors and stuff underneath. So they do, you know, in an ideal world and in a competition, they would absolutely want
to change temperatures between sports.
And so, but isn't that laying a layer of water?
Isn't that what the Zamboni does?
Yeah.
Yeah, it is.
Right.
Right.
Yeah.
Yeah.
It's exactly that.
So Gary, what else do you have for the segment?
So do we need to consider these brushes that curlers use?
And didn't we go through a phase where they had something known as the Frankenbroom? So do we need to consider these brushes that curlers use?
And didn't we go through a phase where they had something known as the Frankenbroom?
Yes, Broomgate.
Broomgate. As it was called.
Broomgate.
Broomgate.
Oh, yeah.
Got to have one of those.
Let me guess.
The broom actually was more abrasive and scratched the ice
to create more pebble-like surface
so that the curl could increase.
Bingo, Chuck.
There you go.
Yeah.
So the brain...
He's pretty much bang on.
Chuck, you've been holding out on us, Chuck.
You're a total curling fan.
Chuck's read Larry's book.
Chuck, you cheated.
It's all right.
It's just research, Chuck.
It's okay.
No, you're right.
So there was a period.
So the brooms that they use now are pretty nylon.
They're not abrasive.
And the job of the sweeper,
the people who are sweeping the brooms
in front of the curling stone,
they are actually trying to melt the ice.
So what they are trying to do
is reduce how much the curling stone curls.
So they want to straighten out the path
of the curling stones.
They sweep furiously,
create this liquid layer,
and that kind of minimizes
how much the curling stone curls,
depending on where you want to put it.
So they're use friction.
Yeah.
That's why they rub it
real fast.
Yeah.
They rub it real fast.
Yeah.
Exactly.
Yeah.
Okay.
We got to we got to
take a break.
When we come back we'll
finish out the curling
controversy here.
We're going to learn
whether Chuck really did
write a book on curling
and performs in the dark
of night and we're going
to find out ice on earth
what's it all about with glaciers
when StarTalk Sports Edition All About Ice returns.
We're back, StarTalk Sports Edition,
with our number one ice expert,
Laurie Winklitz.
Laurie, coming to us from New Zealand.
Thanks for coming in this far
for this episode, Laurie.
Oh, my pleasure.
Yeah.
So I got some leftover questions for you.
I think we saw Chuck single-handedly
solve the broom gate problem.
He did.
With the curling.
And so what I wonder is,
if we move this whole exercise to Earth's surface,
and we get things like snow on the sides of mountains,
skiers care greatly about what the texture of the snow is. Could you briefly
just tell me what they prefer? And do they prefer it because they have more friction or because they
have less friction? So I don't ski, but like a good scientist, I talk to people who ski and they
prefer natural snow. But something we saw in, and we are increasingly seeing in the Winter Olympics is a kind of a reliance on manufactured snow because we aren't getting enough snow in these regions to actually host the Olympic Games.
So skiers definitely prefer the softer, natural snow, mostly because it is softer.
The manufactured snow is, when you look at it under a microscope, is kind of solid little icy balls more like than snowflakes.
And so it's harder.
Why can't we make snowflakes?
Yeah.
Why can't we make snowflakes?
It's the 21st century.
Yeah.
I don't know if anyone's tried, if I'm honest.
We did have a couple of guys, remember?
They made artificial snow, but they couldn't scale it.
Right. Oh, I remember that. Yes. they couldn't scale it. Right.
Oh, I remember that.
Yes, yes.
We have a whole episode on that.
We did, yes.
Right now, or after the show, everybody go to the archives and dig out.
We have a whole episode.
Gary, I forgot all about that.
Yeah.
They had perfected it, and the question was,
did they make enough of it to be useful on an entire mountainside?
Yeah.
Is what that was.
But, okay.
And we need to check back with those guys because if they've conquered that scale issue, that's an investment opportunity.
Okay, Chuck.
All right.
So, Lori, let me hand you some low-hanging fruit.
You ready?
So, what happens if it snows
and the snow never goes away?
As in formation of a glacier?
Yeah.
Ding, ding, ding.
It's so funny.
See, this is,
these are tricks,
see people,
you just found out
what a trick question is to a scientist.
You know, when you ask a question that is so simple, they're like, what the hell is happening?
A small amount of panic just rising up in my chest there.
So what's the difference between the era of the growth of glaciers and the era of the loss of glaciers?
Like what's going on?
Why does it happen one way at one time and the other way the other time?
Because we need snow to form glaciers, we need low temperatures.
And that sounds really simplistic, but a lot of our freshwater systems especially
in mountainous areas they actually rely on glaciers to get freshwater so when they have
less snow because of climate change the glaciers are melting or and or not forming so both of those
um and their freshwater supplies are are you know damaged by that. So climate change is the answer, unfortunately.
Exactly.
And while you're on that subject, just let me just say this,
because people may be thinking, so what?
Glaciers don't affect me.
However, drinking water does affect you.
So no matter where you are, most likely a lot of your places,
your drinking water comes from elevation.
It comes from elevation.
It comes from mountainous areas where we get what's called a snowpack. That snowpack slowly melts in the spring and feeds arteries that feed tributaries, and that brings you your fresh drinking water.
When we don't have the snow because of the lower temperatures, I mean, sorry, the warmer temperatures, we don't have the drinking water.
And that actually leads to a depletion of aquifers.
And it also leads to drought.
So this is why one of the reasons why climate change is so terribly important because you like drinking water.
This public service announcement brought to you by...
No, Chuck's absolutely spot on.
And add to that, Chuck, immigration for crops and for farming.
Absolutely.
Wait, wait, wait.
Chuck, you missed something in that.
What did I miss?
That PSA was beautiful.
Let me just start out by that.
But it's not whether or not it's cold enough to snow,
okay? Because if it rains, that'll also fill the aquifer, right? So what the snow does is it allows
the water accumulation of the winter to return to you in times when it melts.
Exactly.
So, and replenish the aquifer in the spring or whenever the rotation of seasons brings it.
So the problem is you don't have the storage of water as glaciers had provided ever since
the ice age.
That is really the key.
That is the key is point two that I did kind of gloss over is that the snow itself is the
storage of the water.
Yes, yes.
Which is nature's incredible mechanism.
Because when it rains, people say, so what?
So it rains.
Rain is then runoff.
So think of it that way.
Right, right, right.
Good point.
Good point.
And at the bottom of every glacier, there's a river coming out the bottom, right?
Yeah.
But is it always a river? Is it not that cold that it actually freezes to the the bedrock it depends on the
glacier to be honest like the glaciologists who i've interviewed over the last while have said
that no two glaciers are the same you know so some some parts of a glacier will stick to the bedrock
whereas you might also get these kind of streams like
neil mentioned that form underneath the glacier too so you have a combination of kind of sticking
ice and slippery water and you also the weight of the glacier it's kind of as if it's on a hill
if it's in a mountainous area it's kind of constantly moving forward because of internal
deformation so you have all of these forces acting together to cause the movement of glaciers.
Wait, wait, explain.
Wait, wait.
So the ice I make in my freezer isn't rolling out of the freezer on the floor.
So why would frozen water or packed ice move at all?
I mean, why?
It's just sitting there.
I don't care if it's on a hill.
It's frozen there.
Oh.
Why is it going to flow?
I don't get it.
How deep does...
How much...
How...
I don't get it.
All right.
Okay.
Calm down.
Okay, challenge accepted.
So you have a combination of sliding at the base, like we mentioned.
So you have some ice that's sticking on the surface,
and you will have this formation probably due to kind of pressure melting type activities
where you have these streams of liquid water that lubricate the movement.
But you also just have, if you think about ice, it's not an eternally solid material, right?
It is, there's always slight movement.
And this is true for most materials.
On a long enough timescale, a lot of things flow, even things that we think of as solid.
And these glaciers are massive.
They are absolutely enormous.
And that weight, the weight of the ice combined with it being, you know, on a slope will mean that the front part of it is moving ever so slightly more.
And internally, you have this constant kind of movement of ice molecules within the glacier.
What's the difference between ice and compacted snow?
Yeah.
Because a glacier is compacted snow.
Yeah.
So what's the difference?
Very, very good point.
So when you have, so the way a glacier forms is you have the snow, it densifies over time.
You get these, the ice molecules, the water molecules get tighter and tighter and tighter
together.
And in that process, air gets squeezed out.
So you start to lose the kind of white fluffiness aspect of snow, which has lots
and lots of air involved in it. And it starts to turn into something that looks a lot more like
ice. So it's much, much, much denser. So the ice, the snowflakes effectively lose their structure
and they turn into this kind of granular ice surface. And that at the first stage of that,
I think is called fern. So it's a particular type of ice that has been created from snowfall.
And then after decades of this kind of cycle of, you know, snowfall, melting, compaction, all of that stuff,
you will actually get ice deep in a glacier.
And you may have seen this in images that looks blue.
It has so little air in there that it's almost completely transparent.
And so that's one of the glaciologists I talked to, she described glacier ice as
a type of metamorphic rock because it is formed so specifically on this geological
scale over long periods of time, just like other metamorphic rock.
You still didn't say why it's blue.
Okay.
So, well, I, because it's sad.
It's very, very sad.
I didn't ask you, Chuck.
Well, my understanding of it, which could be wrong, right?
My understanding of it is it's the way that light is scattered through large columns of solid water.
It's kind of similar way to the oceans looking blue to us.
It's how light scatters.
Oh, okay.
That's cool.
Or like the sky.
Yeah, or like the sky.
Light scatters, reports into the sky.
So, Laurie, do we look at glaciers as kind of like,
you talked about them being like metamorphic rock.
Are they not like a little bit more like plastic
with the deformation and the way that they'll crevasse?
Oh, I like that.
They'll crevasse and then they'll start to move.
They'll be a free...
Yeah.
Okay, yes.
That's a great observation, Gary.
It is, especially deep down in the glacier
where the deformation is kind of constant.
Whereas on the surface of glaciers,
you'll sometimes see these big crevasses
and that's because
the ice or snow
at that level
is a lot more brittle.
But down in the base
of the glacier,
it's much more like a plastic
than anything else, really.
Yeah.
And you need those crevasses
so we can dig out
the dead cavemen, okay?
Fell in looking for food.
It was Louis.
He didn't come back
for a week.
All right, let's keep going.
No, it's true, right?
Some of our best DNA
are the retreat of glaciers.
And we get prehistoric creatures,
including humans,
coming out of it.
Yeah, because there's no air.
It's so condensed
that it is actually
quite good at preserving stuff.
That's why they find
woolly mammoths in the permafrost.
Yeah.
Laurie, let's go back to Neil's point about those ice streams
that are very rapid and come through on the base of glaciers.
Now, did we not have something recently where there was
what they called an underwater tsunami created by one of these or a whole load of
these ice streams that come through out of the ice sheet. Yeah, that does sound familiar. I'm not,
I don't think I know enough about that in particular to mention it, but I do remember
seeing something a few years ago now, and there was a particular glacier.
I'm going to say Greenland.
I apologize if that's wrong.
But it was moving.
It was found to be moving something like 40 meters a day,
which is much faster than it really should be moving.
Yeah, that's no longer a glacial case. Yes.
No, it's an ice tsunami, right?
Right.
But you can run away from that one.
That's right.
It's true, yeah.
See, the thing is, everybody looks at glaciers and rising sea levels,
and they see the face of a glacier or the ice sheet just collapse into the ocean.
But this is now the double whammy of ice streams coming through
and the collapse of an ice sheet's face.
It's speeding up.
I mean, particularly in the Western Atlantic.
Isn't it true that this water lubricates the flow of the glacier?
Yeah, it really does.
It does, right?
And not only that, it weakens the structure beneath so that it's collapsing.
So think of it as like when you're
making a, if you have a little, a tunnel
but then the water
itself is the drill that made the
tunnel. And you have more water coming
through the tunnel so it's
a self-exacerbating
process. And if it's moving
then it's not going to freeze as well.
Right. And you
need refreeze as a part of the process.
Listen, this is serious stuff.
We're screwed, people.
I must ask you this, Laurie.
When it's cold enough for water to freeze or a frost to occur, it doesn't always.
water to freeze or a frost to occur.
It doesn't always.
And there must be some reasons as to why,
if it's minus something, there's no frost.
What is it?
Air pressure?
Is it?
What is it?
It's a combination of different things.
You do need cold temperatures.
That's kind of obvious, I suppose, like you said.
But you also need things like nucleation points, so something for a water molecule to cling on to for long enough to form a crystal, you know, to form an ice molecule.
You do need that as well.
And temperature wise, there's also this thing called the dew temperature.
And so in most aspects of normal life, the dew temperature, the dew point, I should say, and the freezing point are pretty similar.
But you do also need that nucleation point.
So like Chuck mentioned earlier, you can have liquid water at temperatures well below freezing if you don't have something for those water molecules to cling onto to become ice.
All right. Thank you.
onto to become ice. All right. Thank you. By the way, I would add to that, that there's more than one source of thermal energy reaching the surface of a pond. If you want to call it, let's say,
when you're thinking of a puddle, right? Well, the puddle freeze over overnight. And so you have
whatever retained temperature the ground is from having heated during the day.
So even if the air above it drops below freezing, the pond might delay against that because
it's got heat from the ground.
But also, there are layers of the atmosphere that if there's a pocket of warmth, it can
radiate to the puddle.
And that's a second source of energy that could prevent it from freezing
at a freezing point.
So I'm saying there's more
thermal physics going on.
And only when all the rest of that
gets used up,
all that other heat sources get used up,
then the air temperature will win for sure.
But Laurie,
give us some parting thoughts here.
What should we think about going forward?
And I'm afraid to go to Chuck because he'll give us another
public service announcement and we don't have time
for that. So,
how about you?
What's the future
of ice research, Laurie?
What can we look forward to?
What I'm kind of hoping to see is some interesting
work around, can we
design surfaces so that they
you know change how ice forms on them you know maybe maybe we could not that we want to seed
glaciers necessarily but if we could design surfaces that would allow ice to form very
efficiently that could be interesting for lots of reasons the other end of that scale is there
are lots of industries who don't want ice to form on surfaces like the aviation sector, right?
You don't want ice forming on your plane.
So that's kind of the other end of the same question.
So I definitely like to see more around that space.
And whether it's scalable or not, I have no real sense.
I think probably not at this point.
Where do we find you on social media?
I'm on Twitter, Laurie underscore Winklis.
And I'm on Mastodon as well with the same handle.
Wow, Mastodon, okay.
Mastodon.
And your most recent book?
My most recent book is Sticky,
and there's a whole chapter on ice in there,
lots of curling controversies as well.
Oh, there it is.
There it is.
We'll look for it.
Sticky.
Love that title.
All right, we got to call it quits there.
Laurie,
delight to have you back on StarTalk.
And this surely won't be our last invitation to you.
Thank you.
The Winter Olympics is surely just around the corner.
And no better time to get you back on than that.
Chuck,
Gary,
always good to have you there,
man.
Pleasure.
Always a pleasure.
All right.
Neil deGrasse Tyson here,
your personal astrophysicist, as always. Always a pleasure. All right. Neil deGrasse Tyson here. You're a personal astrophysicist as always. Keep looking up.