Daniel and Kelly’s Extraordinary Universe - Listener Questions #29
Episode Date: February 5, 2026Daniel and Kelly answer questions about bark beetles, ambipolar fields, and gray hairs!See omnystudio.com/listener for privacy information....
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Beatles and fungi are decimating trees in Seattle.
Do any other invertebrates ride fungi into battle?
How can the ambipolar field ignore Earth's magnetic might?
And why is it stronger on Venus?
Could it grow here one night?
Is it true that stress can turn your hair gray?
My world is kind of a dumpster fire right now, so I'd prefer if it didn't, okay?
Whatever questions keep you up at night, Daniel and Kelly's answers will make it all right.
Welcome to another Daniel and Kelly's Extraordinary Universe, another listener questions
episode, we've done 29 of these. You know, we haven't actually done 29 of these. This is the 29th.
We're doing the 29th of these. There you go. All right, so my question for you today, Kelly, is when
did you start to go gray? Oh, man. Gosh, a long time ago. I started getting a few random grays
towards like the end of undergrad, I think. And then in grad school, it started speeding up. My mom started going
at 18.
Wow.
And so I kind of anticipated it would happen.
But I didn't realize that I was really starting to go gray until a friend of mine told me
that I was, quote, rocking the salt and pepper look.
And I gave him the stink eye because I thought of myself as someone who had a few stray grays.
And I hadn't realized I had transitioned to salt and pepper.
But it was very nice.
And so I, anyway, I've transitioned to salt and pepper, apparently.
And what about you?
I can't, you've got some grays, right?
It's hard to tell on the river.
side camera?
I think I might have one or two gray beard hairs.
Oh, you, Daniel.
That's not fair.
I know.
But I think I'm still pretty much all original color up top.
Wow.
Congratulations, Daniel.
Yeah.
Well, there's some mythology in my family.
My grandparents on my dad's side both had jet black hair into their 80s.
Wow.
But there's discussion in the family about whether or not they died it.
And some people are like, oh, of course they died.
How naive are you to believe that an 80-year-old had black hair?
And I don't know.
Maybe they did.
Who knows?
I'm not going to exhume their body and do some tests.
Scandalous.
But so far, in my personal experiment, no gray's up top?
Yeah.
Cool.
I don't know.
I don't really.
It doesn't keep me up at night that I have gray hair.
Like, yes, I was a little surprised, but mostly it's just because I'm not very self-aware.
But at the end of the day, like, I don't care enough to diet or anything like that.
I'm not losing sleep.
And what comes after salt and pepper before you're fully silver-haired?
Is there another stage there?
I don't think so.
I see.
So once you're past salt and pepper, you're just all in.
I think then you're at Silver Fox.
Ooh.
And then you go white.
And then you're Gandalf.
Yeah, I look forward to becoming Gandalf.
I'll get there.
The white wizard.
Well, that's the thing is people are like, oh, you haven't turned gray yet.
But I think gray adds gravitas.
It's nice for people to think you're younger than you are.
But then it also makes them take you less seriously sometimes.
Yeah.
But something that I do want to take very seriously are the questions in the minds of our listeners.
Because our goal is to give you a tour of everything that's extraordinary in the universe,
but not just the things that we find extraordinary, the mysteries that tickle your minds.
So if you have questions about how the universe works, please write to us to questions at
Danielandkelly.org.
Today's questions were taken directly from those messages.
And you'll see that Daniel wasn't just gloating at the beginning of today's episode, although
that might have been part of it.
We did get a question about graying hair towards the end.
Humble bragging.
No, that was just bragging.
Just straight bragging.
There was nothing humble in there.
That's fair.
All right.
So let's move on to question one from Eric.
and let's go ahead and hear that question now.
Hey there, Extraordinaries.
Eric and I had some technical difficulties,
so I'm going to go ahead and read his question,
and rest assured the answer has already been shared with Eric.
The question is regarding the spruce bark beetle in Alaska
and their relationship with fungus.
I understand that they're born with the fungus,
which is parasitic to spruce trees,
which knocks back the immune response of the trees to resist the beetle.
The beetles are a delivery mechanism for the fungus.
Is this relationship unique to Beatles?
So he spells beetle, B-E-A-T-L-E.
Is he talking about the insect or the rock band?
I am going to go ahead and assume that that was an autocorrect
because when I was going ahead and taking notes a couple times my phone
and Google Docs auto-corrected to the band spelling.
I guess the band is much more popular than the invertebrates.
Well, but there are more kinds of beetles, the invertebrates.
than Beatles, the singers, right?
Yep, yeah, many, many.
Yes, there's, I think, you know,
there's probably something like 6,000 bark beetle species
and there's, yeah, far fewer beetle members.
And you're not prepared to answer the question
if the context were rock musicians.
Yeah, no, that's right.
Although I did just listen to the rest of history
did a few series on the Beatles,
but no, I'm probably not prepared for a whole Beatles episode.
All right, so tell us about the bark beetles
and the relationship with spruce trees.
Okay, so there's a lot of different species of bark beetles, and some of them kill trees. And recently there have been some mass tree die-offs as a result of bark beetles.
So sad. Yeah. But so, you know, a lot of the beetles that are causing these die-offs are native, which I think makes the story a little complicated. So, for example, in Alaska, you have the spruce beetle. It's native. And usually it goes after unhealthy trees. And when its population numbers are pretty low, it doesn't cause a lot of.
of trouble. Like it takes trees that were already kind of on the way out, maybe hastens their demise a bit,
but that's not a big deal. Do you mean it goes after the ones that are unhealthy like it knows or that
it just has success against those? Oh, good question. I don't know if it's specifically going after the
unhealthy ones or if it just is better at the unhealthy ones because trees do have something like
an immune system defense. And as we're going to discuss in a moment here, the Beatles have a fungus
that helps them with that immune system defense.
Amazing.
Yeah, but it could be. So, you know, the Beatles, I don't think they're like randomly, blithely going about their life not making any decisions. I think they probably can, to some extent, tell if they are near a tree that is going to be easier or less easy to invade. And so probably they're searching for the unhealthy ones that they'll have an easier chance with. But at high population numbers, though some of those unhealthy ones might get crowded and they get pushed out to healthy ones. Let's say that's what's happening. And so when they get to really high population densities and there's loads of these.
these beetles all over the place, they start killing the healthy trees too.
And so, for example, there's been an outbreak of these beetles in Alaska and something like
1.6 million acres have been impacted. And that means a bunch of, yeah, many, many of these
native trees, native spruce trees have been killed in Alaska. And there's another outbreak of
the Eurasian spruce bark beetle that's happening right now in Europe and it's decimating the
conifer forests.
And so, you know, as I mentioned, a lot of these beetles are native.
And so the question is, you know, like, I think a lot of us are bummed out because we like forests and we like trees.
Yeah, living trees.
Living trees, right.
And the idea that beetles are killing a bunch of trees stinks.
But I guess the question is, is this a natural process or not?
So, you know, when a bunch of trees die, they fall and that clears forest floor to suddenly get sunlight that was.
getting sunlight before because the trees were blocking it. And now you can get flowers and
pollinators. And this is sort of how ecosystems turn over. Ecosystems are not usually stagnant.
And so I guess the interesting question to me is, is this like a 200-year cycle and we just
kind of weren't taking notes before and we're just seeing something that naturally would have
happened? Or would the 200-year cycle have included maybe like one hectare of trees dying,
but because of global climate change or because we've managed forests in a way that, you know, has made more trees unhealthy, is it just way more intense than it's ever been in the past, in which case, you know, maybe we care now because we have made this problem much worse than it would have been. Does that make sense?
Yeah, but I had the impression that some forests were truly ancient, you know, that forest can be fairly stable. If the climate is stable, et cetera, then trees can grow for hundreds or thousands of years.
So it's not like there's a 200-year cycle where all the trees in the forest die and then get replaced.
And that's just what we're seeing, right?
It feels like we're seeing a shift in the capacity for forests to exist.
Right.
Out here in the West, we see lots and lots of dead trees on hillsides.
And it feels like maybe we're seeing the ends of forests.
Well, so first of all, when I said 200, I probably should have said X because I was just picking a number.
But so I was listening to In-Defensive Plants, which is a great plant pod.
And they had a guy on there who studies Bark Beatles.
And he was saying that, like, you know, we really don't know if this is a natural cycle or if it's something that's getting much worse.
And we do think that probably it is a problem that has gotten much worse.
But for a lot of this stuff, we don't have great data.
Because if X is a thousand and it's like a thousand year cycle, we probably wouldn't have great data on that.
Maybe every 1,000 years, you do expect to see all the trees on the hillside's dead.
And then the cycle starts again or something.
But it wouldn't surprise me to hear that we have made this.
problem worse through global climate change and exacerbating drought and stuff like that.
But let's get back to the beetles and the fungus.
Yeah, so what are the beetles doing to the trees and how does the fungus help?
Okay, so the beetles arrive at a tree and they like, you know, for example, they might go under
the bark and the adults might move around under the bark and when they do that, they introduce
a fungus.
And this fungus, the only way it can get from like tree to tree is it travels with the beetles.
And so that's how the beetles benefit the fungus.
So then the fungus infects the tree.
And it does a couple different things for the beetles.
One of the things that it does is that the tree has a bunch of chemical defenses that it would use to make the beetles sick and kill them.
And the fungus takes those chemicals that the tree was using to defend itself and it neutralizes those chemicals.
So the tree is no longer toxic to the beetles.
Amazing.
Totally agree.
Yeah, it's crazy.
And now instead, the beetle is starting to convert stuff in the tree to stuff that's nutritious for the beetles.
So now it's easier for the beetles to get nutrition from the tree.
The beetles aren't getting attacked by the tree.
In some cases, the beetles are actually converting some of the things that the tree makes into pheromones to attract more beetles to the tree.
Wow.
I know.
It's crazy.
And so then the beetles lay their eggs in the tree.
And if you've worked with like trees before, maybe sometimes you've pulled a piece of bark off.
And underneath, you've seen all of these sort of like almost random lines that crisscross over each other.
Those are the paths of like little baby beetles that have hatched and sort of moved around.
And it's like the path of the food that they ate and the movement.
movements that they made.
Yeah, like these little tunnels that they've dug through underneath the bark.
Yeah, it's very cool to see.
Yeah, they're called galleries.
And I do feel like they're little works of art.
Like, I love that name for them.
And so anyway, this reproduction keeps happening.
And with this collaboration between the beetles and the fungus,
the beetles are able to overwhelm the tree's defenses,
and they can kill the tree that way.
And it's just something that happens to trees worldwide.
This must be a common pattern between beetles and trees.
I remember seeing these kinds of patterns on the back of bark of, like,
ponderosa pines in New Mexico, for example.
Yeah, so lots of trees have bark beetles, like at least one bark beetle species.
Sometimes you can find more than one beetle species living in different parts of trees.
Not all of them are super bad for the tree.
And again, a lot of times it depends on how many beetles there are, how bad the condition of the tree is.
But yeah, you can find these almost all over the world.
It seems to particularly be a problem for like spruces and pines and stuff.
Is it ever good for the tree?
Are they doing anything that's helpful?
I didn't come across examples of that in my reading.
Oh.
Yeah.
It doesn't mean it's not out there.
I didn't read every paper on Bark Beetles, as you can imagine with over 6,000 species.
There's a lot of papers out there.
Well, I don't know why, but I feel myself rooting for the trees.
I mean, I'm not the Lorax or anything.
And beetles have just as much a right to live and to eat as trees do.
But it feels like, you know, the trees have this grandeur and they're supposed to be there.
and the needles are invading, whatever.
So give me a more ecological viewpoint on this.
Why should I not be attached to the trees?
Or should I?
I think you could argue either way.
Like, I mean, I'm attached to the trees,
and when the trees die,
then the woodpeckers that were living in there
don't have a home anymore.
And, like, all of the other organisms
that depended on those trees are in trouble.
You know, I think it makes sense
that we get sort of emotionally attached
to those forests and all the organisms that live in there.
But, you know, the only constant in life is change
and ecosystems do pretty regularly turn from one thing to another.
And so, you know, expecting a system to stay exactly the same can cause problems.
So, like, one problem that humans have caused is we've tried to suppress fires because we thought, well, fires are bad.
But now we've let fuels build up over time.
And now there's tons of fuel.
And so when you do get a fire, it burns extra super hot and it kills everything.
Whereas before there were some species that would have survived a fire that didn't burn quite as hot.
And so, you know, we kind of mess things up when we tinker with it.
So the question is, should we tinker with this bark beetle situation?
And can we tinker with this bark beetle situation?
Like, what could you even do?
They're living under the bark.
And, like, you know, what can you do that would target the beetles or their fungus without messing with the rest of the ecosystem?
Like, it's a really tough problem.
And I don't want to make it sound like I'm saying we should throw up our arms and not do anything ever.
But just that, you know, these are complicated problems that you need to think about from multiple angles.
Yeah, and I definitely have emotional connections to some parts of the ecosystem, you know, like anything that threatens my children, for example.
Oh, yeah.
You know, I'm not just going to be like that. It's in the way of coyotes to tear out the throats of my children.
Like, you know, I'm definitely stepping in there and doing something.
I'll note that one, we got an email from PETA encouraging us to think about things from the animal standpoint a while back.
And when I moved out to the middle of nowhere, I did do a lot of research on whether or not.
it was safe to let my like three-year-olds outside with coyotes. I was outside with my three-year-olds.
And it is very rare for a coyote to go after a three-year-old. But you are encouraged to stay with your
three-year-olds outside if there's coyotes around. But once they get bigger, the coyotes are very
unlikely to go after them. So your children are safe from coyotes at this age, I would suspect.
I hope that's true. Just two days ago, my daughter called me because she was out walking our dog,
and there was a coyote that blocked her on a path.
And she was like, I don't know what to do.
So I biked over there and made my presence known.
Oh, wait.
And so you had to scare the coyote away?
Yeah.
Oh, wow.
Yeah.
They are very brazen in our neighborhood now.
They roam in packs.
They're everywhere.
And, hey, you know, we moved into their neighborhood.
So on the other hand, I don't really want them eating my kids or my dog.
Yeah.
But back to the question at hand.
We're talking about fungi and beetles.
One question I had is these beetles.
are using the fungus to help colonize the tree, what's in it for the fungus and what's happening
when the beetles are not in a tree or are the beetles never not in a tree?
The beetles are pretty much always in a tree or moving from one tree to another, and the fungus
get transport.
So the best way for the fungus to get from one tree to another is by being moved by the fungus.
That's the main thing we think that they get from it.
Okay.
And are beetles the only ones who do this kind of fungus farming?
No.
Really?
Yeah.
So Eric wanted to know, you know, what other invertebrates collaborate with fungi.
And it turns out that there's quite a few invertebrates that collaborate with fungus.
And so fungus farming is a pretty common thing in the invertebrate world.
Daniel, I have a question for you.
Termites.
You look at termites.
What do you think termites are closely related to if you have to guess?
Termites.
Or do you already know the answer to this?
I do not know the answer.
Okay.
They're an insect because of the legs.
They got all those little segments.
They seem kind of ante to me.
Thank you.
Yes.
They do look anti to me.
And so I said something to one of my friends about them being, you know, kind of ant-like.
And they were like, Kelly, they're more closely related to cockroaches.
What?
Oh, no.
And I looked at them for a second.
And I kind of gave them a little bit of the stink eye because I was like, you are either
messing with me or I should be very embarrassed because I am way off here.
And it turned out I was.
way off. Well, I don't have to be embarrassed because I'm not supposed to know.
No. Well, yeah, I wasn't trying to embarrass you like you were trying to embarrass me about my gray
hair earlier. But, ooh, a slice. I'm impressed by the gravitas, your gray hair lends to you.
Oh, thank you. Yes, I looked very mature and commanding of wisdom and whatnot.
Exactly. All right. So fungus farming is seen in some termites, ants, wood wasps, and
Ambrosia beetles. So basically the deal here is that they collect certain kinds of fungus. They
put fungus in a certain area. Sometimes, for example, there are like leaf cutter ants who will
feed the fungus certain kinds of leaves. And then the fungus will break it down into things that are
more digestible for, you know, for example, the leaf cutter ants. So let's talk about the ambrosia
beetles for a second. So the ambrosia beetles will farm fungus and they will bring them into, for example,
like dead trees.
And then they'll create
those galleries
that we were talking about
and they'll sort of lay their eggs,
they'll have their babies
and the fungus will be like
creating food for everybody.
And the Ambrosia beetles
even have little specialized
parts on their body
so that they can carry the fungus
with them from one place
to another.
And so this is like a very close
symbiosis so they can
bring it from one place to another.
But while I was reading about this,
I discovered a cool concept
called
And so while some Ambrosia beetles will bring the fungus with them from place to place and will essentially live with the same strains of fungus for their whole lives, other beetles will steal fungus from others.
And so there are some beetle species who will find an Ambrosia beetle who's doing a good job of farming their own fungus.
They're being good farmers, good stewards of the land.
And then the mycocleptics will come in and they'll steal some of the fungus.
They'll start farming it on a different part of the log kind of close by.
They'll lay their own eggs in there.
Wow.
And they'll essentially steal the fungus.
And so they don't, they're not born with this fungus.
They take it from another organism over the course of their lives.
Wow.
That's a little creepy.
It's a little creepy.
Yeah.
Yeah.
It'd be like your family stealing beans from another family or something, you know.
Because you guys have a close symbiosis with beans and chia seeds.
That's true.
We do.
we are lovers of fermented foods and fiber over here.
Mm-hmm.
Seems like just yesterday that the Two Guys Five Rings podcast
was in Paris for the Olympics.
And now we're heading to Milan for the 26th, Milan-Cortina Olympic Winter Games.
I'm Bowen-Yang.
And I'm Matt Rogers, and we'll join athletes from 93 countries
as Two Guys Five Rings hits the Italian Alps
for the 26 Milan-Kritina Olympic Winter Games.
Open your free IHart Radio app.
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Search two guys' five rings.
And listen now.
Hey, I'm Jay Shetty, host of the on-purpose podcast.
On a recent episode, I sat down with Nick Jonas,
singer, songwriter, actor, and global superstar.
The thing I would say to my younger self is congratulations.
You get to marry Priyanka Chopra Jonas.
And also, you know, you're done.
daughter is incredible. That's beautiful man. Yeah, thank you. It's so beautiful. I can see that got
you a little. Yeah, for sure. Our daughter, she came to the world under sort of very intense
circumstances, which I'd not really talked about ever. Growing up on Disney in front of million,
how did that shape your sense of self? I went blank. I hit a bad note, then I couldn't kind of recover.
And I had built up this idea that music and being musician was my whole identity.
I had to sort of relearn who I was if you took this thing away.
Who am I?
Listen to On Purpose with Jay Chetty on the Iheart Radio app, Apple Podcasts, or wherever you get your podcasts.
What if mind control is real?
If you could control the behavior of anybody around you, what kind of life would you have?
Can you hypnotically persuade someone to buy a car?
When you look at your car, you're going to become overwhelmed with such good feelings.
Can you hypnotize someone into sleeping with you?
I gave her some suggestions to be sexually aroused.
Can you get someone to join your cult?
NLP was used on me to access my subconscious.
NLP, aka neuro-linguistic programming,
is a blend of hypnosis, linguistics, and psychology.
Fans say it's like finally getting a user manual for your brain.
It's about engineering consciousness.
Mind games is the story of NLP.
It's crazy cast of disciples, and the fourths
Fake doctor who invented it at a new age commune and sold it to guys in suits.
He stood trial for murder and got acquitted.
The biggest mind game of all, NLP, might actually work.
This is wild.
Listen to mind games on the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
All right, son.
Time to put out this campfire.
Dad, we learned about this in school.
Oh, did you now?
Okay.
What's first?
Smokey Bear said to.
First, drown it with the bucket of water, then stir it with a shovel.
Wow, you sound just like him.
Then he said, if it's still warm, then do it again.
Where can I learn all this?
It's all on smoky bear.com with other wildfire prevention tips,
because only you can prevent wildfires.
Brought to you by the USDA Forest Service, your state forester, and the ad council.
Okay, we're back and we're answering questions from listeners today.
Questions about Beatles, questions about space, questions about what's
going on on Kelly's cranium. On my cranium. How did we get to talking about my cranium?
Are we going to be talking about gray hairs, salt and pepper, silver foxes later? Oh, yeah.
Okay. We're back. We're back to my gray hairs. We're going to talk about my crows feet, too.
Is there anything else you want to point out that's wrong with me, Daniel? I never noticed any
crow's feet, Kelly. This is the first I hear about them. No, no. You're not. You can't walk back
the problem you started earlier today, Daniel. All right. Let's change.
the subject and hear what Jane has to say.
Hi there, Daniel and Kelly.
I've recently heard about the ambipolar field and I'm fascinated to know more.
It seems to be independent of the Earth's magnetic field, but I don't understand how that can be.
Can you explain?
I've also heard that the field is much stronger on Venus and that's one reason why Venus no longer
has oxygen or hydrogen in its atmosphere.
But why is it stronger on Venus than on Earth?
And was it always that strong?
If not, might it increase on Earth?
I'm loving the show and being able to ask questions.
It's like having a tame professor in the spare room.
So I'm really looking forward to hearing your answers to my questions.
Thank you.
All right, so Jane has a really fun question about electric and magnetic fields around the Earth.
This is a field I think a lot of people haven't heard of.
Yeah, I don't think that I've heard, or if I have, I've forgotten about the ambipolar field.
Right.
So I'm thinking about ambidextrous and you can switch between left and right.
Is that helping me understand ambipolar?
Because it's, no, no.
Okay.
So most people are familiar with Earth's gravitational field.
In a Newtonian picture, gravity is a force, and it pulls on stuff.
And things with more mass get pulled on more strongly.
and that's what holds the atmosphere in place, for example.
Or Earth's magnetic field.
Magnetic fields are generated by charges in motion.
So like currents of magma and other metals inside the Earth, we think generate the magnetic field,
not fully understood with all sorts of weird behavior like the poles move and the poles flip,
all this kind of stuff.
The ambipolar field is something completely separate from both of those.
It's a totally separate effect coming from atoms in the atmosphere being ionized.
Oh, all right. So is this going to have anything to do with the Aurora Borealis?
Not directly, no. But a little bit, you know, a little bit. So what happens is if you have a neutral
particle, like you have a proton and an electron, they're bound together. They make hydrogen, for example,
everything is happy. But sometimes things get hot and electrons leave their protons. And now you have
ions, protons that are positively charged and electrons. Electrons are negatively charged.
And they're separated.
So this is like a plasma.
And in the upper atmosphere, you have high speeds and not everything is bound together.
So there's lots of protons and electrons up there, not just all neutral atoms.
So now you have the gravitational force.
It's going to pull harder on the protons than it is on the electrons.
Why?
Because protons are much more massive than the electrons.
I remember that.
And so what that means is that protons are lower in the atmosphere than electrons.
You get this separation because the electrons are.
lower mass, they're moving faster with the same kinetic energy. So essentially, you get an imbalance,
right? Now you have the electrons higher up than the protons. That creates an electric field
because you have these charged particles. And when you create a separation of charges,
you get a field between them because essentially there's a force that wants to pull them back.
That is an electric field, the ambipolar field, in the upper atmosphere of Earth and also Mars and
also Venus. So that's what the ambipolar field is.
Whoa. Okay. All right. So first of all, can you use that for anything?
You can use it to create like a gun of particles out into space. So for example, this field will pull on particles. It'll pull protons up. And in some parts of the earth, it'll create like a polar fountain. And like at the North Pole, it creates like a font of hydrogen atoms, hydrogen ions actually shooting up and out of the earth. I don't know if that's useful for anything, but it's kind of cool.
Okay, yeah, neat.
And you could also, in principle, use it to help, like, steer satellites.
You know, this one way to steer satellites instead of having thrusters,
just to, like, use the Earth's electric and magnetic fields.
Like, you have a long tether and you twist it and that creates torque,
or you can use it to create thrust.
It's fairly weak, though, so not like big satellites or anything.
But, you know, it adds to the sort of texture of the near-earth environment.
Okay, awesome.
And then, okay, so Earth, Mars, and Venus have it.
All right.
So they all have gravity, but every planet has gravity.
They all have atmospheres.
So you need an atmosphere.
Although Mars' atmosphere is much, much weaker.
So its ambipolar field is also weaker.
Yeah.
And Mars is like, what, 1% of Earths or something?
Yeah, exactly.
Is that all you need is a gravitational field and an atmosphere to have an ambipolar field?
That's almost all you need.
You need ions in your atmosphere also, right?
if it's all neutral particles, you're not going to get an ambipolar field. And that's one reason why
Venus has a much stronger ambipolar field than Earth. Number one, it has a very dense atmosphere.
So there's a lot of electrons and ions to pull apart. But also, because Venus has no magnetic field,
it has no protection from the solar wind. See, we're going to get to the Aurora Borealis connection.
And the solar wind is what creates a lot of these ions in the upper atmosphere. So you have energy
from space, photons and protons, etc., hitting the upper atmosphere, that ionizes it.
That energy from space breaks open neutral atoms to create your ion and your electron.
And because Venus doesn't have a magnetic field to protect it from the solar wind,
a lot of that solar radiation causes more ionization and speeds up those particles because
all this energy is coming from space.
And so that gives you a lot of ions, and those ions are now moving fast.
And so that helps these ions escape.
So that creates the very strong ambipolar field on Venus.
And this is always sort of counterintuitive, like the electrons get higher, the protons get lower,
and so that's the amber polar field.
But then the effect on the other particles is the opposite.
That field is always trying to cancel itself out.
Electromagnetism is always doing whatever it can to cancel itself out because it's so strong.
So you create that field by separating them, then the field has the effect of pushing the ions up and the electrons down.
which is why you get this like font of hydrogen ions.
In a similar way, sort of that if you immerse a metal in an electric field,
the electrons in that metal will move to counter that electric field
because the electric field has pushed on those electrons, right?
So electromagnetism is always doing everything it can to zero itself out.
It doesn't want to ever do anything.
It's just so lazy.
Okay, so it's stronger on Venus.
So is it stronger on Venus for two reasons?
One, Venus has a thicker atmosphere, and two, you're more likely to have charged particles in that atmosphere.
Yes, exactly.
So it's not directly connected to the magnetic field.
It's not caused by the magnetic field in that sense.
I think that was Jane's question.
But it is indirectly connected because the magnetic field will help you prevent ionization of your upper atmosphere,
which would reduce the amber polar field.
And so Venus has a strong one because two reasons, yes, has a denser atmosphere.
And it doesn't have protection from the solar atmosphere.
radiation. Now, we think that a long time ago, Venus was a very different situation. It might
have had a magnetic field before its internal bits seized up and it cooled. It might have had
internal motion, which generated a magnetic field, which shielded it from some solar radiation,
which would have had less ionization. Now it's lost that magnetic field, so it gets more radiation
and a stronger field. Cool. Okay. Now, could Earth get a stronger ambipolar field? Yes. It's
possible that our ambipolar field could increase. But for that to happen, we'd essentially have to
lose our magnetic field. We'd have to be more susceptible to solar radiation. No, thanks.
So that could either be, we'd lose our magnetic field. Which seems unlikely. I mean, we don't really
understand it, and it's been kind of flip-flopping and sloshing around, but total loss of the magnetic
field would require the Earth's internal mechanisms to seize up the way Mars has and Venus has.
And that seems unlikely to happen soon because there's still plenty of activity going on inside Earth.
If it happened, it would be slow and gradual.
Or the other thing is we could have more solar radiation so we could get more ionization.
And that's more unpredictable.
Like that just depends on, hey, is the sun going to burp at us some huge blob of plasma that comes and strips away a lot of the atmosphere or ionizes it?
That could happen in any moment.
You know, just a few weeks ago, we had really strong aurora borealis.
Is that how you pluralizing?
You could see them pretty far south in the United States because of the space weather event from the sun.
And that comes from not understanding the internal dynamics and the chaos of the sun's plasma well enough to predict that.
So, yeah, we could get a stronger ambipolar field if we got more solar radiation or if we weakened our protection from it.
Either one would give us more ions and therefore a stronger ambipolar field.
Neither one of those options sound great for the humans living here.
So let's hope it doesn't happen.
All right, well, let's send that answer to Jane
and hear if it freaked her out or made her feel more at one
with her understanding of the universe.
And let's hear if she's going to kick the professor out of her spare room.
Thank you so much for your answer, Daniel.
I really feel I understand the ambipolar field now,
and I'm very relieved that we're for the most part protected from Venus's fate
by our wonderful magnetic field.
But I do love the idea of a polar fountain.
Sounds like something Santa would have.
Oh, and by the way, my spare room is still available for professors
if you're ever in the north of England.
Thanks for a great show.
Seems like just yesterday that the Two Guys' Five Rings podcast
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Hey, I'm Jay Shetty, host of the Unpurposed Podcast.
On a recent episode, I sat down with Nick Jonas,
singer, songwriter, actor and global superstar.
The thing I would say to my younger self is congratulations.
You get to marry Priyanka Chopra Jones.
And also, you know, your daughter is incredible.
That's beautiful, man.
Yeah.
Thank you.
That's so beautiful.
I can see that got you a little.
Yeah, for sure.
Our daughter, she came to the world under sort of very intense circumstances,
which I'd not really talked about ever.
Growing up on Disney in front of a million,
how did that shape your sense of self?
I went blank, I hit a bad note,
then I couldn't kind of recover.
And I built up this idea that music
and being musician was my whole identity.
I had to sort of relearn who I was
if you took this thing away.
Who am I?
Listen to On Purpose with Jay Chetty
on the IHeart Radio app,
Apple Podcasts, or wherever you get your podcasts.
What if mind control is real?
If you could control the behavior
of anybody around you, what kind of wife would you have?
Can you hypnotically persuade someone
to buy a car?
When you look at your car,
you're going to become overwhelmed
with such good feelings.
Can you hypnotize someone into sleeping with you?
I gave her some suggestions
to be sexually aroused.
Can you get someone to join your cult?
NLP was used on me to access my subconscious.
NLP, aka neurolinguistic programming,
is a blend of hypnosis,
linguistics, and psychology.
Fans say it's like finally
getting a user manual for your brain.
It's about engineering consciousness.
Mind Games is the story of NLP.
It's crazy cast of disciples and the fake doctor who invented it at a new age commune
and sold it to guys in suits.
He stood trial for murder and got acquitted.
The biggest mind game of all, NLP might actually work.
This is wild.
Listen to Mind Games on the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
The more you listen to your kids, the closer you'll be.
So we asked kids, what do you want your parents to hear?
I feel sometimes that I'm not listened to.
I would just want you to listen to me more often
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Listening is a form of love.
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I'm pivotal.
I don't know, Daniel, if you had a professor in your spare room for questions, would you want a physicist?
Or maybe a less smelly profession?
We often have a professor in our spare room because we have a guest room and people come to visit.
And sometimes, you know, you invite a friend to come and visit for official reasons to give a talk.
But then you also want to hang out with them and you don't want to put them up in a hotel.
So they sleep in our spare room and have dinner with us.
And that's a lot of fun.
So often we have biologists and physicists.
or physicists usually coming to stay with us.
And our kids have expressed their lack of enthusiasm for physics or biology-dominated dinner conversations.
Our kids at some point asked us to please stop talking about space law over dinner.
Yeah, I understand.
All right, let's move on to our question from Joe.
Hi, Daniel and Kelly.
I've often heard the claim that stress made me get all these great hairs.
Is there any biological validity to that comment?
And if so, what are the mechanisms? Can your emotional state plus cortisol or dopamine levels,
perhaps, affect this part of your biology? Finally, has it been observed in any other animals?
Thanks so much for bringing some color or salt and pepper to this question.
All right, so Joe's suggesting that gray hair isn't just about age. It might be about stress.
It's about like emotional age, not, you know, cosmological age.
That's right. And so I think it's possible that there are different mechanisms.
at play here. So let's go ahead and leave my old age-related grays to the side. We don't have to
talk about them anymore, actually. Okay. All right. And so to understand what's happening,
let's go ahead and talk about the hair cycle. All right. So you have loads of hair follicles
on your head. I do. You do. You do. One does. Not only is your hair not gray, but you actually
have it covering your whole head.
You are very lucky for a 50-year-old.
Or are we rounding up to 100 now?
Yeah, exactly.
I'm more than 50, so it rounds up.
Okay, all right.
So each of our hair follicles goes through a cycle,
and our hair follicles aren't synced.
So our hair follicles tend to be at different stages of this cycle.
Anogen is the part of the cycle where your hair is growing.
And for the hair on top of your head,
the stage usually lasts about four to six years.
Oh, that's all?
Yeah.
Yeah.
Kind of surprising, right?
Mm-hmm.
And your hair's growing something like half an inch a year.
And early in antigen, what happens is that you have hair follicle stem cells.
And so stem cells are cells that are like, they're like baby stem cells.
There's things that they can become, but they haven't become them yet.
And these are cells that are going to become hair follicles, but they haven't become them yet.
So they're hanging out there.
And when the time comes, they will become hair follicles.
and they're just waiting for the message.
When you get to this early growth phase,
these hair follicle stem cells jump into action.
They make a hair follicle,
and now you've got your hair follicle.
All right, so I have stem cells on my scalp,
my whole life, waiting to become follicles.
Cool, didn't know that.
And you also have melanocytes stem cells.
And so what they're doing is they're waiting to produce melanocytes,
and these are the cells that make melanin,
which is the pigment.
that gives hair color.
And so early in antigen, your hair follicle is being made,
and your melanocyte stem cells are activated to make melanocytes,
and the melanocytes will travel down to your hair follicle,
and they get ready to start making melanin.
So now your hair follicle is making the hair,
your melanocytes are making the melanin,
and now you have hair that has color.
And all of my melaninites have to,
all be coordinated, right, because I have like one color of hair on my head and you have a different
color of hair and my daughter is blonde, for example. And so there's a genetic coding in there that
controls all of the melaninites or melanocytes. Melanocytes. Yes, they're all making the same
color. I see. Yeah. Okay. So the thing that's confusing to me is if they only last for four to six years,
how come I didn't lose all my hair when I was seven? Because there's a cycle. Okay, so you've got four to six
years, and then you go into a phase called the catagen phase where everything sort of degenerates.
You lose the blood vessels, and so now the hair follicle isn't getting oxygen or nutrients,
and this lasts about two weeks, and at this stage, the melanocytes die. But your melanocyte stem cells
are still alive. So you still have cells that can make more melanocytes, but the melanocytes that
were made a few years ago, they're toast. Okay. And then you go into a resting phase, and this can last for a few
months where the hair follicle is just kind of chilling out. And then you go into a phase called
Exigen, where the original hair is shed out because you've started the cycle again. A new hair is
growing and it pushes out the old one. You shed. So you shed something like 50 to 100 hairs a day. And so
that's how many hairs are sort of beginning the process anew. And when you start that process anew,
those two types of stem cells wake up again. They start doing their jobs again. And after the new
hair follicle has started and after the new melanocytes are have gone to work, those two sets of
stem cells go to sleep again for like, you know, four to six years or whatever. They, they do their
job, they make the cells that are going to work through the cycle and then the stem cells go to
sleep. Does that make sense? That makes a lot of sense. And it really helps me understand something
I remember wondering about when I was like a teenager. Young physicist, Daniel was thinking about
hair growth, the way you think about like radioactive decay. You know, I was thinking maybe it was like
probabilistic and hairs would just like fall out.
not randomly, but if that were the case, you'd start with like a full head of hair,
and then you just gradually lose hairs until eventually you had like one super long hair,
which would be the only thing you had.
Clearly, that model does not explain the data.
So I like your model a lot better.
Oh, good.
Okay.
Well, and there's a lot of variability.
Some people have, you know, shorter cycles so their hair doesn't grow as long.
Right.
And the cycle on your body is much shorter, so your body hair is never get as long as the
hair is on your head.
But this is like sort of generally our understanding of how the cycle goes on.
average. All right. And so there's really two different bits there. There's like the hair growing and
the hair coloring. And so tell us about why the hair coloring can go wrong or why things turn
gray. All right. So I found this amazing paper. Zhang at all 2020 in nature did this amazing
set of experiments that sort of like deal with tons of different hypotheses and they really nail it
down in mice. So again, this is in mice. Keep in mind it's in mice. Not in humans. But okay, so first
they say, if you stress out black mice, will they get gray hairs? So they stress mice out a couple
different ways and the mice do start going gray. Are they terrible? No, I mean, they're not
the worst I've read about. I have to imagine how would I stress out a mouse. I might like put it in a cage
next to a cat, not to kill it, but just to like put it in the cage next to it, that would be pretty
stressful for a mouse. Oh, okay. So no, this is nowhere near that bad, actually. So they would
It rapidly changed the light and dark cycles.
They would leave the bedding be a little bit damp.
They would have the cage be sort of tilted.
They'd leave them in a cage by themselves, and they're kind of a social species.
So nowhere near as bad as what you're thinking.
That's very gentle, yes.
That is.
Yes, yeah.
And again, as we've discussed multiple times on the show, before you do experiments like this,
you need to get animal care and use protocols.
And we understand you have to stress the animals out to test the hypothesis,
but you've got to do it in the most humane way possible.
Good.
Okay.
But the most effective and fast method they found for stressing the animals out was to give them an injection of a capsaicin analog under their skin.
So capsaicin.
That's spicy?
That's spicy.
Yeah, that's the stuff that gives you the spicy feeling if you're eating peppers or something.
So they would like internally pepper spray these mice?
Yeah, you always find the most horrible way to say these things when we talk about animal studies.
But I am going to just use the phrase, the injection for the rest of this description.
If that makes you feel better, Kelly, all right.
All right.
Well, do you want to know the answer to this or not?
Yes, I do.
Please.
Thank you.
All right.
So they inject mice with this capsaicine analog, and the mice did get gray, but they got, like,
salt and pepper gray, like me.
Oh.
So it wasn't, they didn't turn completely gray.
It wasn't patches.
It was exactly what you would expect if you had hair of follicles on random cycles, and some of
them started turning gray.
And did they look at the microbiology of it?
Like, can they see the melanocyte dying or doing something?
or giving up or...
Yeah, so that's the next thing that they did.
So next they said, okay, we know that we've got these mice
that will turn gray sort of like humans do.
So what's happening?
So then they decided they were going to,
for the stressor, they were going to just keep using this injection.
So then they used the injection and they looked at what was happening
with the melanocytes stem cells and with the melanocytes.
And what they found was that the melanocytes stem cells were, like, disappearing.
Oh.
But the melanocytes were staying where they were.
And so all of the melanocytes that had already been made were fine.
They kept making the black pigment for these black mice.
But the melanocytes stem cells were gone.
So the next time a phase started again, no new melanocytes were made, and those hair follicles would become gray.
So gray is the default color.
If you don't have a melanocyte, then it's just gray.
Yes.
Right.
And so they're like, okay, where did these melanocite stem cells go that are supposed to be there to make sure you've got the cells to give you color every time?
time the cycle starts again. So that was the next question that they wanted to ask. And so one
idea that's been going around for a while is that when you get stressed out, something about your
immune system attacks your like hair follicles and something about that makes it so that
your hair goes gray. And so we've done so much work on mice in the lab now that you can just like
pop open a mouse catalog and you can order mice that like have various parts of their immune
systems that don't work anymore. And so they like ordered some mice that don't.
have T cells or don't have B cells or like they're lacking various parts of their immune cells.
Meaning that there's like an industry that manufactures mice with specific deficits that are
useful for scientific experiments. Yes. Yeah. So they essentially ordered some mice who don't
have like good immune systems in a variety of different ways and they gave them these injections
and they still went gray. So that was pretty good evidence that it's not something about the immune
system that's important for creating this gray. So the next question they wanted to know was,
okay, well, is it something about stress?
And usually when you are thinking about stress,
you think about cortisol or noradrenaline.
So cortisol is a hormone that humans make,
and we release it in times of stress,
and what it does is it helps us, like, mobilize energy.
So, for example, if you're being chased by a lion,
you want to make sure you've got as much energy available,
as many, like, calories that you could send to your muscles or whatever,
so that you can run away from that lion,
It's not going to make you faster than you usually would be, but as fast as you're able to be, they want to make sure that you can be to try to get away from that lion.
And then after that stressor, it tries to help your body recover from this massively horrible thing that just happened to you.
And so for us, that hormone is called cortisol.
Mice have a closely related version called corticosterone.
And so they wondered, okay, maybe it's something about corticosterone that causes graying.
And so it turns out that the melanocyte stem cells have resell.
for corticosterone.
And so what that means is that these stem cells
can bind to corticosterone.
And what usually happens when a receptor binds to a hormone
is that that hormone is sending some message
to the inside of the cell that the cell needs to do something.
And usually what that something is,
is like you need to go into your genetic blueprints
and start making some new compound.
Yeah.
Yeah.
So what they did, amazingly, is they said,
okay, we're going to essentially take the receptors
off of the melanocyte stem cells. And now we're going to inject the mice with the Capsasein
analog and see what happens. And those mice still got gray hairs. So it wasn't about the
glucocorticoid stress hormones because even when that hormone can't talk to the melanocyte stem
cells, you still get gray hairs. Are you with me? Because this is kind of confusing, but it's
beautiful how they're doing this step by step. I didn't follow glucocorticoid, but I think I do understand
And the argument here is that these melanocytes stem cells, the things that you need in order
to make new melanocytes, are disappearing, and they have a button on their outside that responds
to this stress hormone.
But when they disabled that button, it didn't change anything.
So they don't think that pressing that button due to stress is killing these melanocytes.
Thank you.
Yes.
That's a great way to say it.
Okay.
Okay.
Perfect.
And they have another button for noradrenaline.
And noradrenaline is just another chemical your body makes me.
you're stressed out, but it comes from different places.
It can either come from your sympathetic nervous system,
so it can come from nerves that talk to your hair follicles,
or it can come from these like glands that sit on top of your kidneys.
They figured out that if you remove this button for noradrenaline,
they don't turn gray.
Oh.
And they figured out that the message is not coming from on top of the kidneys.
The message is coming from the nerves.
Oh.
I'm simplifying a little bit because I realized I was getting a little bit.
because I realized I was getting a little too in the weeds.
But anyway, it is coming from the nerves.
Wow.
And they were actually able to, like, use this neurotoxin
to keep the nerves from sending the message to the hair follicles,
and they didn't turn gray when you, like, messed with the nerves.
So it's definitely the nerves that are sending the message to the melanocytes
that is essentially making the melanocytes disappear.
And what's the connection then with stress?
Is something about the stress that makes the nerves send this message?
Yeah.
So you stress someone out.
Their sympathetic nervous system, their fight or flight system is like,
ah!
And they've released noradrenaline, and that noradrenaline binds to the melanocyte stem cells.
So the button on the melanocyte stem cells has been pushed.
But if they are in the phase where they're supposed to be sleeping,
you've woken them up from their sleep.
And they kind of freak out.
And instead of, I don't know, going back to sleep,
they start doing something totally unexpected.
They all start turning into other kinds of cells.
I think they're turning into melanocytes.
And then they migrate away.
And so by the time this process is done, you don't have any more stem cells.
They've all done what's called differentiated, which is a fancy way of saying they've turned
into a final version of a cell and they can't make new like melanocytes anymore.
And then they migrate away.
And so they're not there anymore.
the next time your hair cycle starts again, they've wandered off for reasons we don't understand.
And so something about freaking out from some stressful event totally like discombobulates your melanocyte stem cells and they wander off.
So that makes sense as a mechanism to explain why this happens.
But why would melanocyte stem cells have this button?
Why are they sensitive to the presence of these stress hormones?
We don't know.
Oh.
Yeah.
So there has been a connection between.
pigment-producing cells
like melanocytes
and our nervous system
for, you know, like a really long
stretch of evolution.
So, for example, octopuses
and other cephalopods,
if you stress them out,
they will talk to their pigment-producing
cells to, like, change colors,
kind of like blend in with the environment.
But that doesn't explain
why we have nervous systems
that are, like, talking to our melanocytes
and our hair follicles.
But there is this, like, long connection,
Maybe there's some reason why it still benefits us that we don't know.
But when I read the discussion of this paper from 2020,
they were pretty much like,
not really clear why this is happening,
like what the evolutionary benefit would be.
Maybe it's something that was beneficial millions of years ago
and there was just never a reason to decouple these connections.
Maybe it's not so bad for people who have experienced stress
to advertise that by showing off their gray flowing locks
so people know, oh, you know, Kelly's been through something.
Let me ask her opinion.
That's what she's probably wise because she experienced.
Yes, right, grad school gave her gray hair.
She can tell us to not go.
No, I had fun in grad school.
And so is this only something that happens in mice or is the same mechanism happen in other animals like in people?
I think it happens in other animals too.
Like, I mean, dogs definitely go gray.
I don't know if they go gray for stress.
But like, I think if it's happening in mice, it's probably happening in other animals too.
So I'm guessing this is a pretty common thing.
And this suggests there might also be a treatment available there.
You could somehow protect those myocytes so they don't get that button pressed.
Yeah.
So one I want to note that it's really refreshing to have you be the one mispronouncing a word for once.
I'm like feeling great about that.
And I guess we, you know, we both give as good as we get in terms of picking on each other.
But yes, it does suggest that if somebody has had like a super stressful experience, maybe you could try to,
calm them down in some way quickly in a way that might rescue their melanocyte stem cells.
You'd have to do that pretty fast because once those stem cells have migrated away,
they don't come back.
Yeah, then you've lost them forever.
Wow, fascinating.
I really appreciate this question, Joe, because this was like, this was so much fun to read about.
Like, there were lots of things in this paper where I was like, I have no idea what you're saying.
This is like crazy molecular biology stuff.
But like, wow, this was a cool set of experiments that really like, anyway, I am going to
try to make sure nothing super stressful happens to hasten my decline into silver foxhood.
But I'm sure I'll rock it either way.
Well, fortunately, it doesn't sound like answering this question was that stressful for you,
which is a relief.
So let's send it over to Joe and hear about whether it gives him any more gray hairs.
What a colorful journey to finding that association.
I'd like to mention that this kind of science, where the search for an answer,
becomes a series of experimental steps, is research of the best kind.
It's also one everyone can do in their own way.
Thank you for getting to the root of this question without stressing anyone out.
In the same vein as Kelly, I too have a few hairs of wisdom.
That said, I'm definitely still going for the spicy foods.
Whether your head is black, blonde, bear, or glistening gray, stay chill, everyone.
All right, thank you very much.
Everybody who sent us questions, we really do love hearing from you.
And one reason is that it gives us an excuse to dig into some corner of physics or
biology that we always wanted to understand and never had a reason to spend an afternoon on.
So thank you very much, everybody, for being curious and for sharing that curiosity with us.
Thank you.
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Seems like just yesterday that the Two Guys'
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And now we're heading to Milan
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I'm Bowen-Yang.
And I'm Matt.
Rogers and will join athletes from 93 countries as Two Guys Five Rings hits the Italian Alps for the
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Search Two Guys Five Rings and listen now. Black history lives in our stories, our culture, and the
conversations we still having today. This Black History Month, the podcast I didn't know. Maybe you
didn't either, digs into the moments, perspectives, and experiences that don't always make the
textbook. Let me tell you about Garrett Morgan. Brough had to pretend he didn't even exist just to sell
his own invention. Listen to I didn't know. Maybe you didn't either from the Black Effect Podcast Network
on the I Heart Radio app, Apple Podcasts, or simply wherever you get your podcast.
Hey, I'm Jay Shetty, host of the unpurposed podcast. On a recent episode, I sat down with Nick Jonas,
singer, songwriter, actor, and global superstar.
I went blank. I hit a bad note, and I couldn't kind of recover.
And I built up this idea that music and being musician was my whole identity.
I had to sort of relearn who I was if you took this thing away.
Who am I?
Listen to On Purpose with Jay Chetty on the IHart Radio app, Apple Podcasts, or wherever you get your podcasts.
What if mind control is real?
If you could control the behavior of anybody around you, what kind of life would you have?
Can you hypnotically persuade someone to buy a car?
When you look at your car, you're going to become overwhelmed with such good feelings.
Can you hypnotize someone into sleeping with you?
I gave her some suggestions to be sexually aroused.
Can you get someone to join your cult?
NLP was used on me to access my subconscious.
Mind Games, a new podcast exploring NLP, aka neurolinguistic programming.
Is it a self-help miracle, a shady hypnosis scam, or both?
Listen to Mind Games on the IHeart Radio app, Apple Podcasts, or wherever you get your podcasts.
This is an IHeart podcast. Guaranteed human.