StarTalk Radio - Cosmic Queries – The Hidden Chemistry of Everything with Kate the Chemist
Episode Date: November 30, 2021Is chemistry truly everywhere? On this episode, Neil deGrasse Tyson and comic co-host Chuck Nice answer fan questions about chemistry with Kate Biberdorf, aka Kate the Chemist. Discover the chemical r...eactions that make our world work!NOTE: StarTalk+ Patrons can watch or listen to this entire episode commercial-free here: https://www.startalkradio.net/show/cosmic-queries-the-hidden-chemistry-of-everything-with-kate-the-chemist/Thanks to our Patrons William Kelly, Patrick Weller, Nicholas DeAngelo, George Brietigam, Adam Leos, David Bryan Smith, and Mick Mowchenko for supporting us this week.Photo Credit: despeakrit, CC0, 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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Welcome to StarTalk, your place in the universe where science and pop culture collide.
StarTalk begins right now.
This is StarTalk Cosmic Queries Edition, and today we're going to dip into chemistry.
Chuck, you with me here, Chuck?
I am.
Yeah.
How do you feel about chemistry, Chuck?
I'm waiting for you to dip into it.
Okay.
I have to say that I had a terrible chemistry teacher and ruined the entire experience for me.
You're the walking wounded of chemistry students. You're the walking wounded of chemistry students.
I am the walking wounded of chemistry.
And I won't say his name, but I remember him vividly.
And he would explain something
and then immediately expect us to know
like what the next thing is.
And he would do this, and everyone would sit in the classroom
kind of in this terrified state
because it's terrible to feel completely ignorant,
and it's worse to feel stupid.
Ignorant is one thing, but you feel stupid
when somebody has an expectation
of you that you're not meeting. Chuck, are you still in therapy for this?
This sounds like you got a lot to shake. Right. So then wait a minute. Then, you know, me.
I'm sorry I asked, okay? No, I say what's on my mind. So he didn't like me because
he asked a question and we hadn't covered it.
Right.
And so I said to him in front of the whole class, you do realize you have a degree in chemistry.
This is high school.
And then he said, what are you, a comedian?
And I said, well, as a matter of fact.
And the rest is history.
Well, neither you nor I carry any kind of significant chemistry expertise,
so we went out into the ether.
Oh, yeah.
And we found Kate the chemist.
Kate the chemist, welcome to StarTalk.
Thank you so much for having me.
I'm very excited to be here.
Yeah, excellent.
Can I introduce the lady, please? No, I was just going to say, I can already tell you're going to make
me like chemistry. Just the name, Kate the Chemist. I'm like, I need to hear more. So you're,
because that's what we call you on the internet, but park the curtains. You are Professor Kate Biberdorf, and you're on the faculty at the University of Texas at Austin in their Department of Chemistry.
So this is just way excellent, and you've written books.
Previously, just for kids, but recently you have a book that came out a few months ago for grownups.
So that's cool.
I'm going to have to get the
title here. It's Elemental, the Hidden Chemistry of Everything. I love the title. And so Kate,
let me ask you, is this finally grownups get to create a fire in the carpet in the living room?
Yes. Do we now have the permission? That's what the book is. I teach you how to do fireworks
right in the middle of your living room.
No, that's everybody's memory of the chemistry kit growing up.
But the kids do it all the time.
I hear all the time.
The parents come up to me after these shows because I blow stuff up for kids.
And they keep asking me these questions.
And they're like, my little kid has this question about sunscreen.
I was like, your five-year-old has a question about sunscreen.
And they're using their kids to ask the questions.
So in the book, I literally just went through and answered all their questions.
It was really fun.
Oh, I got you.
Okay, cool.
In fairness, it could have been a very vain five-year-old.
That's true.
That's true.
It's like, I got to keep this tight.
I have got to keep this tight.
I know I'm five, but I'm thinking ahead.
So what is Kate, Chemist's fiction series?
What is that?
There are seven books, so five fiction ones, and then there's two nonfiction ones.
But the fiction series is this little 10-year-old named Kate the Chemist, and she goes around her neighborhood and solves any problems in the neighborhood using science.
And it was just so fun to write because for the first time ever, I could, like, make stuff stuff up. Like you can't do that in the chemistry world. You can't lie about things. And so here I could
just have little kids breathing fire and it was just an absolute blast. Wow. So what is one
scenario that might be solved with chemistry in terms of like a mystery or a problem in a book
series? So the very first one is called Dragons Versus Unicorns,
and it's the little kid's musical. Very scientific.
Chuck, she says she made this stuff up, and it is called fiction.
Okay. Chuck, learn the definition of the word fiction, Chuck.
Well, to be real, honestly, that's kind of the reason why is they're trying to get people who
might be intimidated by science. Like some kids don't want to read a, honestly, that's kind of the reason why is they're trying to get people who might be intimidated by science.
Like some kids don't want to read a science book, but they might want to read dragons versus unicorns.
And so it's a way to kind of hook kids, especially little girls, and get them excited about science.
And in the series, little Kate goes around and she's kind of the director of the musical.
And there's all these problems like the unicorn's horns fall off.
And so she has to make blue using science to get it to stick.
So it'll stay on the forehead.
So there's a lot of little ways I can seek it in there.
And it's just a blast.
I had so much fun writing it.
I thought you would tell me what dragon breath is made of.
See, I'm not happy unless.
I absolutely can tell you.
That's also in the book.
That's also in the book.
And so.
Oh, really?
Yeah, yeah, it is.
And so what she does is.
So in the very beginning, we have the little girl breathe fire.
And it's just this big experiment.
And so it was really exciting.
But they wouldn't let her do it in the musical.
So it's a big deal.
So they end up using Cheetos and liquid nitrogen.
So you dip the Cheetos into liquid nitrogen, give it a second, and then you can bite down in it.
And when you exhale, you end up breathing.
It's gas.
It's smoke, right?
You do the condensation.
But yeah, so there's a little bit of dragon breath in there.
Okay, so it's smoke dragon breath,
not flame dragon breath.
No, no.
The editor had a little bit of a problem with that.
As a chemist, if dragons actually breathe fire,
like smog, right?
As in the desolation of smog.
As in the desolation of smog. Yeah, that story.
As in the desolation of smog.
So smog, you see his belly actually glow red,
and then the inside of his throat becomes very hot,
and then boom.
It becomes radiant, and it's ready to come out.
Yes, okay.
And then there's a plume of fire.
From a chemist's standpoint.
Yeah, Kate, explain that.
What would be that fire?
I'm serious.
How would you justify that scientifically?
Now, come on, we know we've got to suspend disbelief,
but if we could justify that scientifically,
what would be that fire?
Well, I could tell you what fire is.
Fire is a combustion reaction,
and it's any time you have a source of fuel, you react it with oxygen, and then you form carbon dioxide and water. That's the traditional one. And so what you're seeing is the release of that energy exothermically being shot out. I breathe fire using cornstarch, which is a lot easier, a lot safer, but that doesn't start in my belly. I just put it in my mouth and spit it out. Well, you're saying there's a safe way to breathe fire.
Yeah.
You just said that.
Yeah.
Okay.
As opposed to the dangerous ways of breathing fire, I can do it safely.
Yeah.
Okay, how about this?
I got one.
I got one.
I got one.
Okay, so as we all know, there are anaerobic microbes deep in our gut, and they release methane.
Normally, the methane comes out the back end.
But if you could somehow reverse that tube and then have it come out of your mouth and then ignite it,
then you could breathe fire with methane, a gas that you produced yourself.
So there you have it.
Basically, dragons have flatulent mouths. with methane, a gas that you produced yourself. So there you have it.
Basically, dragons have flatulent mouths.
They're fart faces.
I said it for you, Chuck.
Fart face. There you go, thanks.
That was the joke, so thank you.
Normally, I don't steep lower than you go,
but I did it.
You know, I'm always getting the letters.
It's true.
It is true.
Why are you always trying to bring Neil deGrasse Tyson down?
That's so funny.
All right.
So, you know, this is actually a Cosmic Queries edition because, you know, we hardly ever have chemists.
And I'm embarrassed by that because chemistry is, you you know some of my best friends are made of chemicals and so we need more chemistry
in this show so chuck you've got you collected questions from our patreon members because this
is a cosmic queries that's right and and kate i'll be coming back to you about your periodic table
and you know intermittently because i me and periodic table go way back too i got me neil's another lover of the period oh don't don't get me started on the periodic table
but okay all right all right no what i want to do i want to try to because i know the periodic table
from the through the lens of an astrophysicist so and and and kate you clearly are a chemist with your periodic table. I'm going to come at you with some astrochemistry.
Oh, great.
Just to see if you can hang with the astrochemists, all right?
We're going to try that a little later.
Let's do it.
Oh!
The gauntlet has been thrown down.
We're going to have to go into the octagon for this one.
Oh, my God.
Two nerds enter, and they both leave,
but just one of them with a little more respect.
Yeah.
That's hilarious.
It's Nerd Thunderdome.
I would watch that.
Yeah, yeah, me too, me too.
All right, so what do you got, Chuck?
All right, let's just jump into it.
Who we got here?
We have the artist formerly known as James Smith.
Hello, Dr. Tyson, Dr. Bieberdorf, and Chuck.
Chuck, if you mess up my name, you should just give it up, buddy.
Bro, I really got to read these before I go.
Here's my question.
Where do we find lithium on Earth?
And how can we find more of it?
Does it exist on other planets?
I love you guys.
Have a great day.
Let me give a handoff to Kate on this.
It is made in tiny quantities in the Big Bang.
Very tiny quantities.
But it is made, unlike most other elements that have to wait for billions of years for stars to create them in their cores. The Big Bang itself makes a little bit of lithium. Now,
let me hand that over to Kate. So it's OG. It's an original gangster.
The OG. I've been here from the beginning. Don't call it a combat. Kate, we need to call them the
OG elements. We need that. I love it.
I love it.
Oh, that's really funny.
I'm going to have to pitch that.
We'll see what people say with that one.
Lithium is like most of the other metals.
We find it in oxide form a lot of times in mines.
I believe lithium was discovered back in the 1800s in Sweden,
and it was formed with an aluminum silicate as well. So there's a little bit of
aluminum there and a little bit of silicon mixed in. So it's in the mines, just like all our other
metals. You find it deep in the crust of the earth. So you're saying it doesn't come in its own
veins through the crust? It's mixed in with other elements?
Most of them are not. I know that we do have it in oxide forms. I don't know if we can find it by
itself. It's very possible. But the forms I know of it are in the oxide forms. I don't know if we can find it by itself. It's very possible,
but the forms I know of it are in the oxide form.
So there's an oxygen attached to it somehow,
which just makes it stable because otherwise it'd be extraordinarily reactive.
So before we move on, let me ask this.
So if iron is our core,
do we find different-
The core of earth.
Yes, the core of earth, sorry.
If that's our core,
do we find different elements at different levels?
Or is it just kind of all mixed in and then, you know,
how does it work in terms of like as you get down to like the iron,
do you find different things at different levels as you go down?
Chuck, the heavy stuff is in the middle and the light stuff floated.
That's all.
It's not that complicated.
Is that it?
Yeah.
Jesus. It's seriously that easy is it really that easy wait just to be clear we think of rocks as
heavy because they like sink in the water but the water is floating on the rocks and the rocks are
floating on everything else that is heavier than they are that went to the center of the earth
so rocks are light by comparison.
So here's a question, Kate.
How do you get, why didn't all the iron go to the middle of the earth?
How can we have these ores of iron that come up into the crust?
Well, it has to do with attractions, right?
Every single one of these atoms have protons in the center and electrons on the outside.
And it just has to do with what it interacted with on its way down to the center.
So if it sees a lot of the oxygen, it's going to have a reaction with that.
We all know rust happens so readily here, right?
Right, right.
So things are going to rust out at certain points before.
Exactly, yeah.
So just it's what it interacted with.
That's what chemistry is all the time.
What is in its environment?
What's its system?
What's its surroundings?
What's going on around it?
What can it do?
So when we find these ore deposits, they're just distracted
iron.
They were on their way.
They were on their way and just like, what's that?
What's that oxygen atom?
Check out.
Hey, oxygen, what's up? Too late.
Bam. Frozen air.
Oh, damn it. I missed it.
Midnight train to Georgia just left.
All right, we got to take a quick break.
When we come back, we'll pick up our Cosmic Queries
with Kate the Chemist on StarTalk.
Hey, I'm Roy Hill Percival, and I support StarTalk on Patreon.
Bringing the universe down to Earth, this is StarTalk with Neil deGrasse Tyson.
We're back.
StarTalk. Cognitive Queries. With Kate the Chemist. We're talking. StarTalk.
Cognitive Queries with Kate the chemist.
We're talking about chemistry.
Something we don't do often enough, Chuck.
I think this is, you know, we do so many other things,
and we've got to give some chemistry its due.
And so we've got Kate.
Kate, a professor of chemistry, associate professor of chemistry?
Yeah, of instruction, yeah. Yeah, I'm instruction, yeah.
Yeah, yeah, at the University of Texas at Austin.
And we're delighted to have you.
You're Kate the chemist.
And what are your social media handles?
I am at Kate the chemist on Instagram and TikTok.
I just hit 100,000 followers on TikTok, which I'm so excited about.
Wow.
Which I know is not a lot for you guys, but for me, that makes me very happy. No, 100,000, excuse me.
100,000 is a lot for anybody.
That's for anybody.
Yeah.
I just made a mental note.
I got to get on TikTok.
Yes, please get on TikTok.
It's so fun.
I really enjoy it.
It's a very easy way to communicate science with other people and just give them little
snippets and I'm really enjoying it.
I never thought I'd say that ever, but I'm really enjoying it.
Yeah.
Cool.
Very cool.
Cool.
All right.
So, Chuck, what do you got for us?
All right.
Let's just jump right in.
These are still Patreon members, right?
All Patreon.
All Patreon.
We changed the rule.
They're the only ones who get to ask questions.
If you are interested in asking us a question, Patreon is the way you have to do it. It was a way for us to kind of democratize.
Actually, just the opposite.
Just the opposite.
Just the opposite of democratize.
I'm sorry.
It was a way for us to cull the pool.
It's not to democratize, to monetize.
That's the word.
All right.
Exactly.
All right, go for it, Chuck.
Yeah, here we go.
This is Max Madison. He says, go for it, Chuck. Yeah, here we go. This is Max Madison.
He says, hey, Dr. Biberdorf, why do you think many scholars, including Isaac Newton, believed in or practiced alchemy even as recently as the 1900s?
Do you think it was for greed or was it truly for the pure pursuit of science?
Oh, good one.
Or was it truly for the pure pursuit of science?
Ooh, good one.
Plus, Kate, I would add to that.
From the alchemy I've read, there seemed to be some mysticism in there as well, at least if you go far back.
So how does all that square working its way so deep into the Industrial Revolution, for example?
Well, it's really funny because from a chemist's point of view, when we think of alchemy, it's just more of the study of chemistry before we knew what was going on. And it was just people mixing things together and trying to kind of cook here and there. And sometimes they came up with medicines that were
helpful and sometimes they came up with crap that was not helpful at all. And so it just depends on
kind of where you fall. And so for me, when I think of it, it just is like the chemistry before,
you know, the 1900s before we had any clue what was going on.
So is it now with that is eye of Newt on the periodic chart?
Yes, here it is, right there.
Have you seen, I saw this comic once.
It was vegetarian witches, right?
And so it was Eye of Potato, Head of Lettuce.
Oh my God.
It was.
That's pretty funny.
That's awesome.
Yeah, it was.
So, anyhow, yeah, so that's a really good answer.
I like that.
So what you're saying is it's the best people could do before they really knew what was going on.
But why is it such an insult, though?
You know, when you say, oh, he's just an alchemist.
And it's like people will fight you if you call them that.
But you're saying that it should not carry a stigma.
I don't think of it.
Yeah, that, yeah, exactly.
Like, I don't honestly think of it with a stigma. I think of it as people doing the best they could with what they had.
I mean, this was pre-internet.
This was before we were sharing information so easily.
You know, this is just what they had available to them.
So I don't think it's negative.
I don't want to have to school you in this way,
but we are post-internet,
and there are people who think Earth is flat.
So don't think the internet fixes stuff, okay?
No, no, that's not what I meant.
That sound is exactly what you meant.
No, no, no, it's not.
It's a way for people to communicate,
for scientists to tell each other and share information more readily.
And that's all I mean by it.
And so before we had that, it was much more difficult to actually do it.
Oh, you have an elitist internet.
Well, you'd have to go to the library and you'd have to read a book and you'd have to find that very specific book.
And so it's easier to find that information on the internet.
That's all I'm saying.
But yeah, maybe.
Oh, okay.
See, she's on the internet for smart people.
Internet for everybody else.
We got flat earthers, vaccine deniers.
We got all these.
I have a hard time with those.
We are on the DAI.
The dumbass internet.
That's what we are on.
The DAI.
All right.
All right, what else you got, Chuck?
Give it to me.
Here we go.
This is Elias Siametis, I think.
How do you spell it?
S-I-A-M-E-T-I-S.
So either Siametis or Siametis.
Siametis.
All right, I'll give you.
You got a 50% chance on that one.
50% chance, right?
And Elias, if I messed up your name, change it.
Chuck don't play.
Chuck, Chuck, Chuck.
Make my life easier.
There you go, man.
All right, here we go.
Hello, Dr. Tyson, Dr. Bieberdorf, and Lord Chuck.
Oh, man, look at you.
That's so funny.
He says this, and I love this.
What are some fun chemistry experiments that I can do at home for my twins
other than the ones in your books because we have done those?
At what age do you think it is appropriate or beneficial to get them started? Oh, well, let's start with
that one immediately. As soon as they can start talking, I think it's really important to get
that inquiry in mind, try to ask questions. And I think it's really important, too, to announce that
you don't know everything. And it's okay not to know everything. As a scientist, that's what we're
doing is exploring. We have questions and then we're searching for answers. And so if you can
kind of break down science into that right at the young age, then kids
love science.
It's all fun about explosions and exploration.
What I would highly recommend is try elephant's toothpaste.
That's not, well, it didn't, the kid's version is in my book, but do the big kid version.
Grab 35% hydrogen peroxide from a medical supply store.
Order potassium iodide off of Amazon.
Don't use yeast because yeast isn't going to do anything,
but order potassium iodide.
Use dish soap.
Make sure it's not natural dish soap.
Natural dish soap doesn't have high surfactant in it,
so it doesn't bubble as much.
And so like Dawn dish soap is fantastic.
Add some food coloring.
Use a big flask, an Erlenmeyer flask is best,
and add it right together.
Add potassium iodide last.
It's going to shoot out the top as the hydrogen peroxide decomposes. I mean, that's just a winner. Everybody loves that.
Everybody loves that. They love that. Kids love it. Outside, it'll destroy your ceiling.
Doesn't it make a big mess? Yes. Yeah. But there's tarps and there's also things like you can wash
stuff outside. No big deal. Did you see the internet video where they did a um a version of that where it is
almost half a city block that they filled with that what yeah what it's insane they made a set
it's like half a city block uh as as a square a half a city block square and they just did
they filled the whole thing. It's
insane. It is. It's insane.
It made me so nervous because they did one right before
that where I don't think their safety was up,
personally. Like, it got too close to them. I don't think they were
wearing anything. It made me so nervous that they were going to get
just covered in this stuff, which is just not good for your
skin. Yeah, I saw that
one, too, and they're running away
from it in that video.
It hits the house! And I'm like, yes.
I'm like, you people are insane.
Yeah, okay.
But I'm glad it was a cool video.
No one got hurt.
So that's all I care about.
Wait, wait, Kate, does that mixture
have any utility at all
other than the demonstration of a geyser?
Well, to be honest,
I use it in my classroom to talk about either stoichiometry or catalysis.
And so you can talk about how you can use another molecule to come in and break apart
a certain molecule into new pieces.
Because what happens is hydrogen peroxide decomposes into oxygen, gas, and water.
And it's extremely exothermic, so it's really hot.
So your students can actually feel the heat.
So you can talk about it in thermodynamics. You can talk about catalysis. Oh, yeah. OK. So it's very exothermic, so it's really hot. So your students can actually feel the heat. So you can talk about it in thermodynamics.
You can talk about catalysis.
Oh, yeah.
Okay.
So it's very educationally helpful.
Yeah, it's very educationally helpful.
Instructive.
Yeah, yeah, yeah.
Okay, cool.
So can you now, and I'm going to say, I just want to stop you because I don't care if I don't know something.
Yeah.
That's why I love doing this.
Stoichiometry and catalysis, you sounded like you just told me I was going to die.
I'm sorry, Chuck, but you have stoichiometry and catalysis.
Oh, no.
You have six months to live.
So I don't know what those are.
Let me break it down.
No, no, no.
Our stoichiometry tells us that you have the catalysis.
Yeah.
Okay.
Stoichiometry is just the chemistry version
of dimensional analysis.
So, if you're saying, like,
I'm going 60 miles an hour
and I have 100 miles to go,
how long is it going to take me to get there?
That's dimensional analysis.
So, it's just basic unit conversion.
So, akiometry is you throw molecules on top of it.
So, you got a little carbon dioxide,
you got some methane,
and you just go through the math.
And so, you can do that with the decomposition
and go through how much oxygen you would expect to produce.
And it's a very fun, I say fun exercise
because it means the explosion.
And catalysis, you've probably heard of catalysts before.
And so that's where you just have a new molecule
and it takes two other molecules and brings them together.
And so it's essentially a,
it's like the highway for a reaction
instead of the back roads.
So when you throw in a catalyst, it allows it to go way fast and it's on a much faster route and it's essentially a, it's like the highway for a reaction instead of the back roads. So when you throw in a catalyst, it allows it to go way fast.
And it's on a much faster route.
And it's just better, usually.
Otherwise, it's a bad catalyst.
Awesome.
That's great.
Thank you.
Good, good.
All right.
What's next, Chuck?
Here we go.
This is Roman Pruckup, who says, hey, hey, Dr. Tyson.
Do they ever say where they're from?
I always like knowing where they're from.
No, they don't say, Dr. Tyson. Do they ever say where they're from? I always like knowing where they're from. No, they don't.
Okay.
Yeah.
I mean, guys, if you want to start including that for Neil,
that would be great.
I will definitely include it in your question.
Roman Precup says, hey, Dr. Tyson, Dr. Bieber tour.
Lord, nice.
What is stopping us from using H instead of Li in Li-ion batteries, which I believe would be a lithium-ion battery, right?
Theoretically, they should be able to form the same connections with other elements,
and H is lighter than Li. So hydrogen lighter than lithium. Is it only because H is the only
S1 non-metal element? You know what? I was
understanding everything he said right up until that point. Now you're just showing off, Roman.
Wait, wait. I got to slip in here, get a little astrophysics. So you may remember on your periodic
table, hydrogen is listed twice, sort of as a gas and as a metal. Oh, we have a live demonstration of it there.
So under very high pressures,
hydrogen takes on the properties of metals.
And in the center of Jupiter, which is 90% hydrogen,
the hydrogen manifests as metal.
And it conducts electricity,
and it does all the things metals do.
And Jupiter has a ferocious magnetic field as a result of it.
But everywhere else, hydrogen is just like regular hydrogen.
So, Kate, over to you.
So, it's a gas.
So, the main difference is it's a gas.
And so, lithium is going to be a metal.
We can force it to be in the aqueous state so we can dissolve it in water, but hydrogen is a gas.
And so, that immediately changes everything about how it would operate.
One thing we always talk about is how we could eventually try to replace a gas tank in a car with hydrogen gas. And so when I say gas tank,
I'm actually talking about the liquid that you pump in your tank, whereas hydrogen gas-
Gasoline. Gasoline.
Yeah. Thank you. Thank you. That's what I'm trying to say. Gasoline. Whereas hydrogen gas
is an actual explosive gas. And it would be really, really dangerous to put that on our car
if we got into an accident, because that would be a huge explosion like that's unbelievably flammable and stored under pressure it's super dangerous if it
gets knocked into um so that's one of the biggest hiccups is that it's a gas and it's flammable so
it's very dangerous and we have to take care of it all lithium flammable as well so there's pieces
of that i was about to say a lithium version of flames too doesn't it yeah i was like i was like
yeah i'm i got a feeling lithium might be in the same category
since they're telling me to take my battery out of my suitcase when I'm flying.
Okay, so maybe it's just not as flammable and explosive.
Is that a fair characterization?
That's fair.
And it's stored under pressure, like you said.
That pressure component really changes things.
Yeah.
Right.
All right.
All right, so then.
But just to be clear, and that S1 little
ditty he put at the end there, if I understand that correctly, Kate, correct me if I'm wrong,
that lithium appears directly beneath hydrogen on the periodic table and everybody in a column
in principle can make the same families of molecules. And this is what all he was saying
there, right, Kate? Yes, that's exactly right. So both hydrogen and lithium have one electron in their very first shell, that external valence
spot. So in the 1S shell, hydrogen has one. In the 2S shell, lithium has one. Yeah. Okay. All right.
Well, I got to say, chemistry is a lot of fun. It is fun. I'm so mad at your teacher. When Kate is teaching it.
Yeah, oh my gosh.
You were talking about that.
I was ready to jump through the webcam and hug you.
Like, it breaks my heart when I hear that chemistry teacher.
You're awful.
I hear it all the time.
It's so bad.
Kate, you're not helping me here.
Yeah, no, Kate.
No, Chuck did need a hug in that moment.
This is true.
He needed a hug.
He did.
Clearly I did because I didn't even realize I was harboring all that.
All right, let's go to Jim Kelly.
And Jim Kelly says, hi, Dr. Bieberdorf.
When I took chemistry in college, it was the late 80s.
I had a lab partner who told me the story of when the chemistry in high school,
he mixed some things together that caused a cloud of gas to billow forth.
My vague memory was that it was green.
When the teacher saw it, he yelled to the class to evacuate immediately.
Luckily, no one was hurt.
I don't remember what he said the cloud of glass he created was, but I'm curious.
Do you have any idea what chemicals would be available in a high school chemistry class that could cause this kind of event and what indeed was produced.
Hey, Chuck, you pronounced my name Jim.
Man.
You know what, Jim?
People don't have any confidence in you, Chuck.
No, I know. That was wrong, Jim. That was wrong.
Jim, Chuck was having a hard day today,
so look what he did to you.
So, Kate, you know any magic green gas cloud recipes?
Chlorine.
I'm sure it's chlorine gas.
It's what the teacher was afraid they made.
So chlorine gas is yellow-green.
It's not good to breathe in.
It can go into your lungs.
It dissolves in the water vapor that's in your lungs,
and so it forms hydrochloric acid.
So then you have acid in your lungs.
It can burn, burn, burn.
You're burning up from the inside?
Yeah, it burned.
It's terrible.
It's absolutely painful.
So wait, so Kate, wait.
So Kate, if chlorine is a gas,
but of course when mixed with sodium, it's just salt,
why do we fear hydrogen in a battery if if it's gas but then if
it mixes together with something else it's no longer a gas well it depends on what the phase
would be right and what what it's what its comical compound would actually be just like you're saying
because if it's something with hydrogen partnered with another metal it could be something that
could be right quite reactive so. So in lab, we use
something called lithium aluminum hydride. And so when the hydrogen actually has that electron,
instead of giving it up and forming an acid or proton, instead of when it has that electron,
it can actually be quite reactive and it's very dangerous. So when we use lithium aluminum
hydride in lab, you end up having to take your flask and put it in a liquid nitrogen bath. So
you soak it in something that's at 77 Kelvin or negative 194 Celsius because it's so reactive. So that my gut instinct is I don't
want a battery with that. I don't want to be anywhere near that. All right. But a little
known fact that the orange fuel tank that was the main tank of the space shuttle orbiter when it
launched, it had the two solid rocket boosters on the side. And then the main tank of the space shuttle, Orbiter, when it launched. It had the two solid rocket boosters on the side.
And then the main tank in the middle was, it had two tanks inside of it.
And one of those two tanks is twice the size of the other,
precisely twice the size.
And the one that's twice as big had liquid hydrogen in it.
And the one that was half the size had liquid oxygen in it.
And you blend them together, they pick up a two-to-one ratio,
and out comes the exhaust, which is just water.
And so you're saying we can't do that in a car?
I don't think so, not safely.
Have you ever been around those doers?
The doers are the vacuum-sealed containers that you have to,
in order to keep something in the liquid phase.
So in order to have nitrogen, if you've ever seen liquid nitrogen,
it's kept in these doers.
They're vacuum-sealed containers
because nitrogen wants to be in a gas
in our environment here on Earth.
Same thing with hydrogen.
It wants to be a gas.
You'd have to use a special container
which are ridiculously heavy.
So on top of the fact that things are pressurized.
I just realized.
I mean, that's what's happening in the near future.
I asked you a stupid question
because, of course, those tanks,
they're kept refrigerated until launch.
Right, so, yeah, you can't do that with a car.
There's that.
Not in Texas.
No, not here.
Yeah, you guys don't even have electricity.
Oh, blood drawn.
Sorry, I had to do it.
Oh, all right.
We got to take another quick break.
We come back more with Kate, the chemist, as had to do it. Oh, all right. We got to take another quick break. We come back more with Kate the chemist.
We're loving it because Chuck has learned some chemistry for the first time in his life.
And so, all right.
We'll be back in a moment on StarTalk. We're back.
StarTalk Cosmic Inquiries Edition, all about chemistry.
So our first foray with a pure chemistry episode here, and I'm loving it.
And we got Kate the chemist.
Anybody that's named Kate the chemist, you got to have them on the show.
See? We got Kate, the chemist. Anybody that's named Kate, the chemist, you got to have them on the show.
No one voluntarily just randomly calls himself the chemist unless they can like mix some stuff together.
And Kate, you met your husband in your chemistry department, correct? I did, yeah.
We were both getting PhDs in inorganic chemistry.
We met in Welch Hall.
He was behind me in our Saturday morning seminars and, like, making jokes about things.
And it made me laugh and just fell in love.
Wow.
But now he's in software engineering, correct?
Yeah, software engineering.
He's coding.
He's quite an introvert and I'm quite an extrovert.
So it's pretty good balance.
So, Chuck, so if you have a couple where they both are completely chemically fluent,
So Chuck, so if you have a couple where they both are completely chemically fluent, they have to really stay in love their whole time because that could get really.
Here, honey, drink this.
Exactly.
I was going to say.
That's a terrible.
You don't want to make your wife mad when she knows how to put together concoctions that will burn you up from the inside.
This is nine episodes of CSI ready to be written right here.
I'd have to be very careful about it. That's for sure.
Yeah. Kate, I think you only mentioned two platforms when I last asked. TikTok and,
what was it, Twitter or Instagram?
Facebook, Instagram, and TikTok.
I'm at Kate the Chemist.
On Twitter, I'm Kay with the number eight, the chemist.
Someone else stole my handle there.
Ouch.
I know.
We got people.
We can take care of that.
Thank you.
Chuck, call our people.
I will, without a doubt. You'll have it in the morning, okay?
Thank you.
Guys, thank you so much.
All right.
Chuck, give me some more.
Here we go.
This is Sparrow Chaos.
Sparrow Chaos says,
Hello, astrophysicist Neil Tyson and chemist Kate Bieberdorf and Chuck.
How does dissolving a salt molecule in water make its atoms ionize?
Yeah. Are you ready for this? Okay. It's actually pretty simple. So what they do is they form what
are referred to as ion-dipole interactions. And so the salt goes in and it's in a lattice. So
when you think of sodium chloride, I'm sure you don't think of it in this big cage,
but that's what it looks like.
So there's a sodium ion, then a chloride ion, and then a sodium and chloride and sodium
chloride, and they alternate.
You form this giant cage.
It's a big box.
It's a huge box.
Exactly.
Like a big cube.
Yeah.
So the sodium atom is boxed in by the chlorine atoms.
They're all boxed in.
Structurally.
They're completely surrounded in. Yeah chlorine atoms. They're all boxed in. Structurally. They're completely surrounded in.
Yeah, exactly.
Okay, interesting.
Like a cube, every other corner is a sodium, and then every other corner is a chloride.
And so they just rotate because it's a one-to-one ratio.
And so they're already technically in the ion form when they're in salt because it's a sodium ion attracted to a chloride ion, and that's what forms the sodium chloride.
So they're already together.
And so when that cube drops into the water, they form the ion-dipole interaction. So the ions from the salt, dipoles from the water, because water is shaped in this beautiful little point, kind of,
if you will. So the oxygen's at the top, and then the hydrogens are directly below it. And so this
forms an interaction with the salt, and they come together. It's called an ion-dipole interaction.
Well, I got to show off here. I got to show off.
I have to show off.
It's 105 degree angle.
Is that correct?
It might be.
I know it's less than 109.5 degrees because it's in the bent form.
Oh, okay.
That's all I knew.
I just had to show off that little bit of thing.
That's all I knew.
Okay.
Yeah, that sounds right.
As far as I'm concerned, you're talking about FM radio.
I know, 109.5. Okay. Yeah, that sounds right. As far as I'm concerned, you're talking about FM radio. I know, 109.5.
Okay.
Classic rock all the time, 109.5.
The Ion's coming to you live right now.
All right. All right, very good. Wait, wait, so keep going. So now what? So it just lives that way. That right. All right. Very good.
Wait, wait.
So keep going.
So now what?
Oh, so it just lives that way.
That is the natural state.
Yeah, they break apart.
And so the ions
then kind of separate by themselves.
You have a sodium ion
that's completely surrounded by water.
And so since sodium is positive,
it's going to be attracted
to the oxygen negative side of water.
So the O's are going to be surrounded.
My Michigan just came out.
My O's are going to be around the sodium. O's, yeah. And then the chlorine on the other side of water. So the O's are going to be surrounded. My Michigan just came out. My O's
are going to be around the sodium. And then the chlorine on the other side is negative. And so
that's going to be surrounded by the hydrogen component of the water molecule. So it's
completely going to arrange. So all the ions separate out and they're completely surrounded
by tons and tons of water molecules. And that's what your salt water actually is.
Wow. It's beautiful. Okay. So the whole ocean is this, is what you're saying.
Well, plus a lot of other crap.
There's plastic in there.
There's coral reefs.
There's fish.
There's oxygen.
And fish poop.
Fish poop.
Yeah.
Yeah.
Carbon dioxide these days.
So, yeah.
Yeah.
Okay.
I know.
Sorry to go there.
All right.
Yeah.
She had to bum us out.
All right.
All right. So, Chuck, what else you there. All right. Yeah, she had to bum us out. All right. All right, so Chuck, what else you have?
All right, so let's go from a brine to a food question.
This is...
That's Chuck's only chemistry word he knows.
That was my only chemistry joke that I could do.
You're talking about...
Okay, forget it.
Carrie Manaberg says this.
Hi, Dr. Kate and Dr. Tyson.
This is a food chemistry question.
Is it true cooking vegetables will reduce their nutritional value
and denature some enzymes?
Some raw veggies taste great, but when you roast a veggie like onions.
They taste even better.
They taste so much better.
Yeah, so what does heat do to the big molecules, Kate?
It depends on what the molecule is.
So they're completely right that with your proteins, they are going to denature.
So they go from the crumpled up position.
So they're kind of like on top of each other, the fetal position.
And then they open up to more of a starfish when they apply the heat.
So that's going to change their structure.
So, Kate, what happens when some heat slaps onto some big vegetable molecules or vitamins?
Vitamins, I guess, is the nutritional part of this.
Yeah.
Well, so the molecules for vitamins are either going to be fat soluble or water soluble.
So it depends on how you're cooking them.
So if you have a lot of oil in there, then the vitamins will dissolve in your oil or your fat.
And so that will be pulled out. And depending on if you eat that liquid that's around there,
it's very possible that it will dissolve out of there. Wow. Okay. So if you knew in advance,
whether it's water soluble or oil soluble, you might cook your vegetables differently to avoid
that. Perhaps. But in general, the idea is just to minimize the amount of oil. You don't want
that stuff in your body anyway.
You don't want any of those fats.
You want to minimize it because it's not good for your arteries.
Okay, but I bet what they're talking about, when you roast onions,
you're putting them neither in oil nor water.
You're just slapping those puppies on the grill right next to your T-bone.
So how about if it's just pure heat and you get those little brown marks on your onion?
Caramelization.
Yeah, the caramelization.
Exactly.
I love me some of that. I'm getting onion. Yeah, the caramelization. Exactly. I'd love me some of that.
And so caramelization is when you have your sugars. And so that can be either your complex
carbohydrates, more of your starches, or those could be your simple sugars, which are actually
sugars. And so when you go through caramelization, you're breaking down the sugars, you're breaking
them into smaller molecules. So you are changing their chemical composition, but I don't think
necessarily that's making it better or worse for you, for onions specifically. For me, I'm more molecules. So you are changing their chemical composition, but I don't think necessarily
that's making it better or worse for you, for onions specifically. For me, I'm more worried
about cooking your veggies in a lot of oil or fat. Okay. So it may be that, well, okay, but
surely there's some molecules that don't like the heat and it'll just bust them and break them apart,
right? That's different though. That's talking about if you had too much
heat. So if you had too much heat, then your molecules are going to completely decompose,
like actually break apart instead of breaking into smaller molecules. So it's like whether or not
it's breaking into more of its elemental states or whether or not it's breaking into smaller
molecules that are still tasty and aromatic and give things a smell. Still of themselves. Okay.
Interesting. Yeah. So that's, is that the difference between decomposing and biodegrading? Well, that depends too. So biodegrading is going to be something
that usually happens outside, right? So you have like your, what am I trying to think of? So like
six pack rings, those need to be biodegradable. And so that's when sunlight hits it. So high
energy UV radiation will hit it and do trigger some kind of chemical reactions
as well but those are usually photosensitive chemicals okay okay okay you're checking that
out right all right similar similar it's just speaking of energy speaking of water soluble
uh who who knew who would have who would have known that the Wicked Witch of the West was water-soluble?
You know, that's just an interesting little fact.
We need some chemists to work on that, I think.
I think they got to get some top people trying to figure that one out.
What kind of life form is she where that occurs?
Right, right.
All right, Chuck, keep them coming.
All right, here we go. This is Brady Feicher.
And Brady Feicher says,
Hello, all from Los Alamos, California.
My question is, in the world of chemistry,
is there ever any thought to the possibility
that new chemistry might someday be discovered
in the way that the physical world
is grappling with the ideas of dark matter or dark energy
or in the
same realm of possibilities, like a chemical world that sort of exists maybe in the quantum realm?
So Chuck, this is a movie trailer ready to happen. In a world. In a world. Yeah, I love that question. So, Kate, are we living in the entire one and only
chemistry universe? I refuse to, yeah. Can you imagine a whole other chemical realm
that is apart and distinct from everything we're doing now? Yes, and I think it would be ignorant
to say that we know everything now for chemistry. I mean, we can't figure out how the electron moves across or from the nucleus. Like it teleports from one side of the atom to
the other. We can't figure that out. So to claim that we know exactly what's going on is just
gibberish. But I do think we know a lot more than we did a hundred years ago. So we've made a lot
of progress. I really wish I was going to be alive like two or 300 years from now, because I think
that's when the chemistry is going to be just like, beautiful wow that wow that's like a chef does it kiss your fingers
and pop up your hand we're back to cooking with you that's great but but but wait a minute so in
physics there are entire branches of physics that were discovered right so relativity was a branch
of physics and quantum physics a branch of physics uh so
is there a branch of chemistry you can imagine waiting to be discovered oh man that is such a
good question yeah i'm just extending the question from from our guy yeah yeah i honestly i can't put
a name to it but a hundred percent because i think i just think we don't know everything right now i
think there's so much more to figure out.
We have a decent understanding of the atom, but we still can't see it.
Our microscopes are getting better and better and better, but we're just, it's not perfect
yet.
And so I think that we're so close to learning a lot, like we're right on the cusp.
So hopefully we'll get it soon.
So right now we're playing with atoms, but, and they're doing stuff we just accept.
Yeah.
We haven't gotten in it to say, Hey, I saw you do that. And now I understand it. We just kind of, we agree with each other. This
is what it does. And we make stuff out of it and move on. We haven't found an experiment to break
down our theories yet, but I think it's coming. Okay. Wow. Okay. Yeah. Hopeful. Very hopeful. Okay, here we go. This is Kevin Ho.
Kevin says, hello, Dr. Tyson and Dr. Bieberdorf.
When we hear the word chemist, we often think of some mad scientist working in an underground lab with lots of different beakers and flasks boiling away.
Do either of you know any mad or maybe just kind of crazy scientists in your field?
Kate, other than yourself, you need not implicate yourself in this question. You have immunity,
diplomatic immunity here. So yeah, is it possible to know a lot of chemistry and be diabolical so that you end up doing things nefarious?
For sure.
A hundred percent.
We've heard some really sad stories about people who've taken their own lives because
they know enough and they do it in kind of horrendous ways.
So I don't like that.
I don't like that side.
But I do think that chemists in general are quite fun.
We usually use our skills for good.
So a lot of us, you'll find a lot of us in elementary schools.
Usually.
But we're out there trying to promote science,
make scientists look good.
I want to show that anybody can be a scientist.
It doesn't matter who you are, what you look like.
Honestly, anybody can be a scientist.
If you have a question, technically you are a scientist.
Ooh.
Wow.
Okay. Okay, and can you are a scientist so oh wow okay okay and can you be a scientist if you're not simultaneously wearing a lab coat that's yes that's the question you're in the kitchen
if you're in the kitchen you're cooking so you do it every night cooking is chemistry if there's
anything it's anything it's chemistry chemistry and thermodynamics yes all right chuck let's go
into a fast lightning
round. So Kate, you have to answer in fewer than five words what your questions are. Give it to me.
Okay. Chuck. All right, here we go. This is Gerald Johnson. Gerald Johnson from Seattle. He says,
I have reached a scientific plateau. Has, have we reached a scientific plateau or has science,
discovery, invention just slowed down compared to the days of old?
Kind of what you were just talking about.
Yeah.
So yes or no, Kate?
No, we haven't reached the end of that.
We just got vaccines.
No.
Okay.
She's like, I just got a booster shot.
What's your problem?
Okay. She's like, I just got a booster shot. What's your problem? Okay, it's possible that, I mean, a lot of advances happen on the frontiers of journals
and doesn't always make it into the newspapers.
And then there are, Kate, what are they called,
who bring chemistry into popular products?
Just engineering chemists, you know, chemical engineers, right,
who then do interesting things with it.
So, yeah, yeah. I mean, yeah, do interesting things with it. So, yeah.
Yeah.
I mean, yeah, I have to disagree with the person as well.
I'm on Kate's side with this.
Okay, keep going.
We took more than five words to do it.
Friedrich Johansson says this.
Hello, doctors and lords.
Chuck, don't get too accustomed to that, Chuck. You know what?
I got to tell you. At first, I was like, oh, God, I can't believe this is stupid. Now got to. You know what? I got to tell you.
At first, I was like, oh, God, I can't believe this is.
But now I'm kind of like, I like the sound.
Anyway, Team Seas is the initiative to get funds to remove plastic from the oceans.
Is there some plausible chemistry as a means of removing plastic and, more importantly, microplastic from our seas?
Yeah.
So, Kate, you got like a microbe.
That would have to include biochemistry, right?
Some microbes that would munch on plastic and either, you know, return it to its base
ingredients.
And then die.
And die.
Return it to it.
Or, you know, Chuck, it'll eat the plastic and then it'll become super microbes.
Right.
Yeah.
Be careful what we wish for here.
So, Kate, what's the future of chemists helping the oceans?
I'll give you more than five words.
Because we're going to end on this question.
I'm going to give you more than five words.
Go.
I would say I agree with your answer on that.
The only thing I'd be concerned of is any waste that would then be produced in that reaction.
So if they're producing methane or producing something else,
that could be bad for our environment.
I do think MOFs could be the answer. So metal organic framework. So they're like those cages we discussed before. So they would essentially trap the plastic,
if you will. And then you'd be able to kind of filter that whole thing out in general. So that
might be a future, but it's a long way for that one. Wow. So this is a, it's an incarceration
system where you... Exactly. Yeah. I don't like the sound of that.
Yeah, exactly.
Chuck.
I don't know about that
because you know
what's going to happen.
Now all the black plastic
is all locked up.
Chuck.
The white plastic
still roaming the ocean
just as free as they ever was.
That means it's time
to end the show.
Because Chuck,
we can never reel Chuck back
when he goes on that right
kate it's been a delight to have you we know we're going to want you back
and my one little sort of i have more but i would throw out a periodic table tidbit so we
astrophysicists discovered an element on the sun before we discovered it here on earth. Do you know which element that is?
I thought it, I want to say, Oh God,
it's either going to be hydrogen or helium.
Helium.
Yep. You got it. So Helios.
So we named it after the Greek sun God Helios.
And so that was a rare case where we had better data from the universe than we
did than we can produce here on earth.
So,
Oh yeah.
And so,
so that's my one little,
and I can say I helped.
It's okay.
We're all going to look for your book so that finally adults can blow stuff
up the way you did as kids.
Tell me the name of the book again and where can we find it?
It's elemental,
the hidden chemistry of everything.
And it's sold anywhere books are sold.
Anywhere books are sold. That's the answer now.
Yeah, that's how that goes. All right. Well,
thanks for being a cherished guest
on StarTalk, and I assure you this
is your first and it won't be your last.
Provided you agree. Provided you
survive, Chuck. I'll be back.
You'll think you'll be back.
All right, Chuck. Always good to have
you as my co-host here.
All right, I'm Neil deGrasse Tyson,
your personal astrophysicist.
As always, keep looking up.