StarTalk Radio - Season 4 Time Capsule (Part 2): Cosmic Queries
Episode Date: January 5, 2014Neil deGrasse Tyson, your own personal astrophysicist, answers your questions about dark matter, black holes, light, time, relativity and the fabric of our universe in your favorite Cosmic Queries epi...sodes of Season 4. 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.
Welcome to StarTalk Radio. I'm your host, Neil deGrasse Tyson.
I'm an astrophysicist and director of New York City's Hayden Planetarium, right here in New York City, part of the American Museum of Natural History.
The show you're about to hear is another Season 4 time capsule, this time featuring your favorite Cosmic Queries episodes.
In Cosmic Queries, my comedian co-host and I grapple with a variety of questions asked by you, our audience.
Based on our poll, your favorite Cosmic Queries were all about dark matter and dark energy.
Who discovered dark matter?
And I know it wasn't Al Gore.
Sorry, Al.
He discovered it on the Internet.
On the Internet.
Yeah, so dark matter was discovered in the 1930s by a dude named Fritz Zwicky.
Not Fritz.
That's totally Fritz.
Oh, man.
Look at that dude party.
When did he have time to discover dark matter?
That dude was always at a party.
So he was Swiss born, American.
I don't know if he was ever naturalized, but his whole professional career was in America.
And he worked at Caltech in Pasadena, California, the California Institute of Technology.
And he was measuring the movement of galaxies.
Now, the example I just gave with the sun and our solar system orbiting the galaxy,
he did that same measurement for galaxies orbiting one another in a cluster of galaxies.
So he's measuring how fast these galaxies are moving and says,
the speed they're moving tells me how much matter should be there to account for the gravity.
And he does the calculations and he's off by a factor of five or ten.
Right.
And he double checks and triple checks his calculations.
They continually don't match.
And he said there's missing matter somewhere.
And it was the beginning of the missing mass problem, today known as dark matter.
I love it.
And there you have it.
It was Fritz Wicke.
I think it was 1936.
So he's just covering a math era is what we're saying.
Exactly.
It was called the missing mass problem.
Okay.
And it's the longest unsolved problem in modern astrophysics oh and
not what women are thinking really okay no that would be a longer problem you know a related can
i give a related comment to be in the universe?
Well, so the number that we put forth, well, so let me back up.
We measure the stuff.
And so it turns out when we try to make galaxies, well, I mean, on a computer.
I was about to say, did you just let me in on some top-level stuff that I am not cleared to hear?
We have.
Yeah, that slipped out.
There are men in dark suits coming in.
Hello, gentlemen.
What?
I didn't hear anything.
What?
Yeah, look at this light.
So, it turns out, before we understood how deep the dark matter problem was, we had a hard time making galaxies on a computer.
You put in matter.
You spin it up.
You see if it's self-gravity because matter attracts itself.
You watch the computer provided all your formulae are accurately captured in the program.
Newton's laws of motion, differential equations that track where things move.
And you put it all in there. You load it up. And we found out we can't make galaxies. Newton's laws of motion, differential equations that track where things move.
And you put it all in there.
You load it up.
And we found out we can't make galaxies.
Not only that, we can't make the structure of matter in the early universe unless we put dark matter in the equations.
So something was missing.
Something was missing. And so not only does the universe show us it has dark matter, we need it in our formulations of the universe in order to create a universe that looks like the one that exists.
So we have good theoretical confidence as well as observational requirement that dark matter is out there.
And we think that that missing thing is dark matter and not love.
You need love to make a universe. An absence of love.
No, it's too much love.
It's too much.
It's more gravity than we can account for.
I do have a question based on something that you said, that things enter a black hole, but they don't leave.
Yeah.
Not really.
I mean, they sort of leave, but not really.
Okay, because I'm imagining that the black hole needs like a massive super colonic or something.
Because when she blows, it's going to be awful.
Stand back, everyone.
Yeah, colonic.
I forgot that word.
I never think I'd ever use that word in an astrophysics conversation.
And that's why I'm here.
This is what I bring.
That'd be a great new storefront, black hole colonics.
They would win in the colonics contest, I'm sure. I would see that in an episode of Doctor Who. I feel it coming on.
So black holes eat things. And as far as we know, they stay right there down in their center.
But over time, the black hole slowly evaporates these particles. And Hawking first figured this out.
And it's named in his honor.
It's called Hawking radiation.
And given enough time,
these particles inside the black hole
will evaporate from just at the border
of the event horizon.
That's the place beyond which you don't return.
But I throw in all your atoms,
they come out one by one over time,
very slowly.
So it's an evaporation process and it comes from quantum physics. It's a quantum physics phenomenon, actually. And I can, I don't have,
okay, I can get it in the next 30 seconds because we're gonna have to go to break in a moment.
Okay.
So I'll tell you, Hawking radiation in 30 seconds. Ready?
Ready.
Okay. So you remember E equals MC squared?
Of course.
E equals, energy is equivalent to matter.
Okay?
Mm-hmm.
So on the outside edge of a black hole, the gravitational field is so strong, the gravitational energy is so intense, the gravitational energy becomes matter right at the outer edge of the black hole.
And that matter escapes.
So the black hole evaporates because its gravitational energy is getting converted into matter.
And you know something?
Those particles that escape, invented out of the vacuum of space itself, have the same inventory of all the particles that went in in the first place.
The black hole did not forget what it had eaten.
How does dark matter influence time?
Ooh.
Dark matter, like anything else in the universe that contains energy,
Einstein's special theory of relativity says that time slows down
in the presence of high sources of gravity.
And so if you have a region where there's a lot of dark matter,
if you can find a place near that dark matter that is high gravity from that dark matter, your time will tick more slowly.
Your metabolism will metabolize less quickly.
What would happen if all the dark matter in the universe suddenly vanished?
Awesome question. If all the dark matter vanished, our galaxy would fly apart
because all the speeds
of the orbits
that all the solar systems have
is the right speed
for the regular matter
plus the dark matter's gravity
to contain it.
If you instantly take away
the dark matter,
we fly away
and all the orbits
go cockamamie
and galaxy clusters
fly apart
and everything goes haywire.
Wow, I'm actually starting to get this.
Welcome back to StarTalk Radio and our Season 4 Cosmic Queries Time Capsule.
Next up, Dark Mysteries of the Universe,
where comedian Leanne Lord and I answered your questions on everything from the tiny electron to the higher dimensions of the multiverse.
I have a question from Joe Vera.
And he says, I recently found out about something called Dark Flow.
Isn't that a DJ?
Dark Flow.
Okay, I'm sorry.
Yeah, exactly.
A beatboxing DJ.
Dark Flow. That's a great name. It, exactly. A beatboxing DJ. Dark Flow.
That's a great name.
It is, isn't it? Something like a cartoon.
Alright, now from what I gather, it is the...
The other great name for it was like MC squared.
That's, you know, if you want to be MC.
I'm going to pretend I didn't hear that.
Alright, from what I gather, it is the unexplained
coherent motion of galaxies toward
one side of the universe.
Can you please elaborate on this phenomenon and its possible ramifications for our understanding
of the universe?
Yeah, there's something called the great attractor that got labeled that because when you measure
the speed of galaxies as they move in the universe, there are multiple ways to do this.
One of them is just how fast is the universe expanding.
So that's the speed they have just from the expanding universe. But while that's happening, galaxies are moving
among themselves. For example, we are about to, in 7 billion years or so, about to collide with
the Andromeda galaxy. It's our nearest big galaxy. So we're about to collide, but the greater
activity of the universe is expansion while galaxies are still moving among themselves.
Okay.
Right?
So when you map the speeds of all these galaxies, it was found that there's a whole swath of galaxies in the universe that have sort of an extra motion towards one direction.
Hmm.
So you don't know if they're escaping something or being drawn towards something.
Run, everybody.
So it's an interesting sort of phenomenon
that's not completely explained.
So you just didn't explain it.
That's true.
According to the theory of multiverse,
what is space, and he says I'll call it space,
between universes?
What is the space between universes?
Yeah, it's a higher dimension.
Next question.
Oh!
And not the fifth dimension, as in the singing group. Right, actually, there's a fifth dimension. Next question. Oh, and not the fifth dimension as in the singing group.
Right, actually, there's a fifth dimension in there somewhere.
But if you take the three-dimensionality of our universe and then you embed it among other universes in another kind of space, that's a higher dimension.
And in fact, I hosted a panel on nothing.
You hosted a panel on Seinfeld?
On nothing at my host institution, the American Museum of Natural History.
And we talked about what is between galaxies if the multiverse produces galaxies.
And that's a kind of nothing.
But it turns out it's not the best nothing that you can come up with.
It's like the dark alleys of the universe?
No, because that still has dimensions.
Is it nothing if nothing's there but it still has a dimensionality?
See, we got really deep.
I mean, heads were exploding left and right.
Yeah. In the aisle.
Like now.
So, no, it's what we would call the space of a higher dimension, which is not even our
space, because it would not have the matter.
It would not have the energy.
It would not have the anything that we associated not have anything that we associated with our stuff
or even with where our stuff isn't
because outside of our universe, there's not even the nothing of space.
Wow. No?
Well, because if space is nothing,
then where there is no space, there's not even that nothing.
Okay. Next question. Okay. I'm sorry. I'm not allowed to call not even that nothing. Okay, next question.
Okay.
I'm sorry, I'm not allowed to call next question.
Go for it, go for it.
Because I'm just, what?
Go for it.
I need to go back to school.
Is there anything smaller than the infinitely small,
and can you put it in a way that does not make me hate
that I don't even get to be in pre-calc until next year?
Ooh, high school student.
Yes.
Nice.
Can you smell that?
Young person.
Yeah.
So, by the way, see if you really like math, see if you can skip pre-calc and just go straight
to calc.
Just tell them Tyson told you.
Tyson told me.
Yeah.
I have a note from my personal astrophysicist.
Can I please get in?
And just go, see if you can go straight to Calc.
But, all right.
So is there anything smaller than infinitesimally small?
Yes.
All right.
Next question.
You are so evil.
Okay.
No, no.
So here it is.
The electron is smaller than the smallest thing we have ever measured.
And in fact, it is so small, we do not know how small it is.
We cannot measure it.
It is so small.
In fact, it could be so small as to not occupy any volume at all.
As far as our measurement devices are concerned, it has no dimensions at all.
The electron.
So, the electron comes closest to infinitesimally small of anything we have ever known, thought of, dreamt of, or measured.
Approximately how many stars are born and die each day?
Oh, I love that.
Now, what's a day? How are we defining a day i'm assuming earth day let's assume somebody else's day earth earth right
but of course other planets have days yes in fact venus's day is longer than its year
just chill on that one for a bit so leanne's face just scrunched up in a, like.
Because I'm chewing on it.
I'm actually chewing on it.
That's okay.
Yeah, on Venus, the day lasts longer than a year.
But we'll get back to that if we go there.
So, now, where was I before I distracted myself?
How many stars were born each day?
How many stars were born each day?
So, you can do what's called a back of the envelope calculation.
You ready?
All right.
Yes.
Our galaxy has about, let's just say, 100 billion stars.
Mm-hmm.
Okay?
And the universe has been around for about 10 billion years.
Back-of-the-envelope means you change the number to make the math easy.
But your answer will be—
I back-of-the-envelope my taxes all the time.
But your answer will be approximately correct.
And later on, you can put the exact number in if you want the exact answer.
Fine, tune in.
So say we have about 100 billion stars, and the universe,
and the galaxy has been around for 10 billion years.
Okay?
So if we have 100 billion stars, and we've been around for 10 billion years,
that means the galaxy makes 10 stars a year.
That's an average.
Yeah, on average.
That's right.
If it made 10 stars a year throughout its whole life, we'd have 100 billion stars over the 10 billion years.
That's how that works.
So it makes about 10 stars a year.
So that's about one a month.
And so we don't quite make a star a day on average.
About one a month.
We could live with that.
However, that's not actually how stars are born.
They're born episodically in stars, in stellar nurseries, where thousands of stars are born all at the same time.
So if you're a planet in orbit around one of those stars, you'll see stars lighting up daily as they are born.
It must be pretty.
Well, not daily, but frequently.
Like, poof, there's Brad Pitt.
And poof, there's Angelina Jolie.
How does the Higgs feel different from earlier ideas of an ether?
Oh, did he spell ether right?
A-E?
Yes.
Yeah.
Yes.
The A is silent.
A is silent, so it's a diphthong.
It's a diphthong.
Yeah.
I think it's a diphthong.
That's very kinky.
Yeah.
They should invent a new bathing suit, the diphthong, you know?
Oh.
That would be cool.
So let me see.
We only have like 20 seconds left.
Yeah, because you're fooling around.
Let me see.
Well, I have to give half the answer, and you've got to get the full answer at the end of the break.
But the ether was this proposed medium of the cosmos through which light traveled.
Because people knew that light was a wave, and sound is a wave wave and sound doesn't move through a vacuum, does it?
You remember the bell jar experiment where you have a bell ringing, you put a jar over it, you evacuate all the air and the bell shuts off.
The bell is ringing and you can't hear it.
Right.
It doesn't go through a vacuum, so neither should light was the hypothesis.
Because the ether was a thing, nobody knew what it was, that was proposed to allow light to vibrate its way
from a star to us through the vacuum of space.
Okay.
Because sound needs something to vibrate,
the ground, the air.
Sound doesn't travel through space,
such was the tagline to the movie Alien in space,
no one can hear you scream.
Yes.
However, light travels through it,
so surely there must have been a medium out there through which light can move and vibrate.
And it was proposed to be the ether, but it was never found, never measured.
It was never found.
And it went away.
So is the ether dark matter?
No.
We learned that light does not require any medium at all to vibrate.
It is self-vibrating.
Oh, man.
Don't go there.
Stop.
Stop.
Stop.
Oh, it hurt.
That actually physically hurt.
I'm just talking universe here.
I'm just universe here.
Is it warm in here?
How do you know
math is the language of the universe?
How do we know? Because the universe
tells us.
Eugene Wigner, a physicist
back in the 20th century, commented
on the unreasonable effectiveness
of mathematics. The unreasonable
effectiveness. Because we invented it, yet
it accounts for
the operations and motions of the universe.
Since math is purely logical, it means
the universe, at its finest, is
logical. The math is
Vulcan. Love it.
Adam Young wants to know,
have we considered the consequences
of tapping into the dark side of the force?
And is the dark side of the force
really stronger or just more loose?
Ooh, well, all the forces we know
don't have dark sides.
You haven't met my mother.
I'm sorry.
So, yeah.
Welcome back to StarTalk Radio.
I'm Neil deGrasse Tyson.
This time capsule features your favorite cosmic queries from Season 4.
Next up, an episode we called Answers at the Speed of Light.
Next up, an episode we called Answers at the Speed of Light.
Now, I heard lately that lasers have been used to try to direct lightning strikes.
The laser is shot into the thunderhead clouds and the plasma flows the laser back.
Is there a way to harness this energy and make lightning farms?
Well, first of all, that's the first I've heard of this.
And I think it's amazing.
And I can even explain how it works, even though I only just learned of it.
Because you're that bad.
No, because... Cue music.
I need a theme.
You do.
You're the shaft of science.
Okay.
Now, sorry, I distracted myself.
Where were we?
You did lightning for me, sir.
Lightning, yeah.
So here's what happens.
Lightning comes about because there's a difference in charge between a cloud and the ground beneath it.
Yes.
And charges don't like being separate from one another.
The molecules reach an excited state because they've lost their electrons.
They don't like staying that way.
Okay.
And all the electrons are sitting on the ground, and those electrons want to get back to the cloud.
And so the cloud comes over, the electrons gather, and they're ready to rise up and reach the cloud again.
Thus is born a lightning strike, which tells you that lightning goes from the ground to the cloud, not the cloud to the ground.
Really? cloud to the ground. Now, so if you take a laser that's very high power and you ionize gas at the atmosphere
in one place versus another, you can build charges around where the cloud is and force
a lightning bolt to go where you say so.
Now, that's good.
Yeah.
Now, the person wants to know if we can make a lightning farm out of it.
I say, why not? But it sounds great. You just have to watch out that your lasers aren't so powerful
to ionize the air in places so that you can force a lightning discharge that you're using more
energy than you get back from the lightning itself. Because then that would be inefficient.
Then you're not making a light, you're not farming anything. You're getting less than
what you started with.
Now, it turns out the act of forming a raindrop in a cloud takes some charge out of the cloud
and brings it to the ground.
Okay.
So you're relying on the sun, which evaporated the water in the first place to make the cloud,
to then drop the water, bringing charges to the ground, relying on that in the first place. So if the laser is just to help it out, to direct the lightning where it would have struck anyway, but now you strike it to your spot, your sweet spot, then you got a good farm going.
I'm sorry, my what?
I just had to say, I had to just clarify all of that.
Yeah.
Oh, sorry.
You're what?
I need a moment.
I think I need a cigarette.
The man said my sweet spot.
Who was our most scientifically friendly president?
Like, which one of our U.S. presidents was the most friendly to the field of science?
Ever?
Ever.
Yeah, it depends on what you mean by friendly.
In Washington, friendly means how much money do you give the enterprise.
That's what, in Washington, all that matters is money. What you say doesn't matter at all okay okay then let's go just an fyi got you
okay all right so a few things uh the abe lincoln began the national academy of sciences
now that's kind of cool very set up to establish an advisory board to Congress that was not itself politically motivated for any reason.
And so Congress would call on the National Academy of Sciences to produce studies on scientific issues that befall the day.
I got to put Lincoln at the top of that list.
Okay.
As the most scientifically aware and literate.
So he was not just a cat owner.
I didn't know he owned cats.
He was the first president to have a cat.
I did not know. Why do you even know that?
Because I was getting tired of the slavery thing. Like, what else did he do?
How can we determine the difference between a brown dwarf and a large rogue planet?
Oh, it's hard. Brown dwarf is a star that didn't make it. And a large rogue planet is just a big old chubby planet. There are astrophysical differences between the two, but they're very hard to notice from a distance. So it's very hard. It's one of the big challenges. And we got low mass star people and high mass planet people meeting in the dark of night trying to solve that problem.
You said chubby planet.
problem. You said chubby planet. Joshua Jenkins wants to know why does the Earth spin in the direction it does? And what if Earth started spinning twice as fast as it does now? Okay,
so we spin this direction because I'm going to say it exactly physically. You ready? Yes. That
is the direction of the angular momentum of the entire solar system. So we're going with the flow.
Beautiful. We're going with the flow. The sun spins that
way. All planets orbit that way. The moons orbit that way. Everybody is going counterclockwise as
viewed from the top. Now, why do they want to spin up Earth? I don't know. That would have the length
of the day. There would be 12-hour days instead of 24-hour days. Oh, I can't get enough done.
The act of spinning us up, okay, we'll feel that.
That would not be a good day on Earth, all right?
Okay.
You will know when Earth starts spinning faster.
You know what will happen?
Stuff behind you will run into you, and you'll be flattened against it, and you'll be a pile
of goo on the wall behind you.
Ew.
Because right now, you're moving 800 miles an hour with the rotation of the Earth.
If you all of a sudden start going 1,600 miles an hour, something came in behind you to push you to do that, and that will flatten you into a pile of goo.
Welcome back to StarTalk Radio and our Season 4 Cosmic Queries Time Capsule.
One of your favorites was an episode on the science of timekeeping where the comedian Chuck Nice and I discussed nearly an infinity of timely topics.
I've been hearing a lot about this theory that if we place a giant mirror 22 light years away from away and point it at an extremely efficient telescope, we would see things happening in real time in the past.
That's what he's saying.
So I think what he's saying is if you were to put a mirror 22 light years away from Earth,
point it back at Earth, would you be able to see Earth 22 years in the past?
No, you would see it 44 years in the past.
Right, because it's got to go there and come back.
Do the math.
Yeah, you got to look at it and then it's got to come back and come back. Do the math. Yeah, you got to look at it, and then it's got to come back to your eyes.
Exactly.
So you see yourself in a mirror, not as you are, but as you once were, two billionths of a second ago.
Gotcha.
If you're a foot away.
If you're a foot away.
Light travels a foot every billionth of a second.
Okay.
One foot per nanosecond, if you want to be exact.
We came up with the number 22, I don't know.
Stick a mirror out there, let the light go and come back.
You will see however many light years away, double that because it's the round trip time.
That's how far in the past you were viewing events on Earth.
So you're viewing the events that you're actually looking at the past in real time
for you.
Yes.
Gotcha.
Yes.
Gotcha.
That's exactly what's happening.
That beam is on its way to the mirror and it's on its way back and you're catching it.
Right.
Right.
That's all.
And by the way, we see other objects in the past because their light has just reached
us.
So this is not magical thinking.
Right.
My favorite is a galaxy that's 65 light years away.
I'm sorry, 65 million light years away.
It's a galaxy called M100.
M100.
M100.
65 million light years away. It's a galaxy called M100. M100. M100. 65 million light years away.
And guess what they're seeing on Earth right now if they had a telescope big enough?
What?
The extinction of the dinosaurs.
Look at that.
That's so cool.
That beam of light that conveys the information that they got slammed is just now reaching them.
It's just reaching them.
Because they're 65 million light years away.
And when did the dinosaurs go extinct on Earth?
65 million years ago away and when did the dinosaurs go extinct on earth 65 million years ago you got it is the perception of time universal or do we all perceive time
differently i wonder if a house fly and other organisms perceive time to be quicker it's fun
to think about other life forms that live shorter or longer as perceiving time differently. But typically when we do that, we are humanizing their life.
Right.
So one dog year is seven.
Seven human years.
Yeah, dogs don't care about humans.
They care.
But the passage of time as measured by the atomic vibrations of atoms within them is the same for everyone.
Okay.
Oh, yeah.
So that's it. On an yeah. So that's it.
On an atomic level, that's it.
That's it.
No difference.
You can slow it down, speed it up with relativity,
but otherwise, if you put the frog and the mayfly and the human and the elephant together in a room,
the passage time is the same.
I got you.
And that makes great sense for dogs,
because that means a dog would be licking its butt for about two months.
Total out of its life.
How would a space faring people keep time?
Oh, that's good.
Okay.
Just they-
Real simple.
Look at their watch.
No, there's an important, do you know what time it was on the moon?
No.
It was Houston time.
That's funny.
Right?
Because they're talking to Houston.
That's so funny.
Houston is telling them when to wake up and go to sleep. Oh my God, you're absolutely right. You pick a spot on earth and that becomes Houston time. That's funny. Right? Because they're talking to Houston. That's so funny. Houston is telling them when to wake up and go to sleep.
Oh, my God.
You're absolutely right.
You pick a spot on Earth.
Right.
And that becomes your time.
In space.
If you had an actual colony, space colony, that was nowhere near Earth.
Right.
And you didn't care about Earth, then you're not dependent on the rotation of the Earth or daylight or nighttime.
You can create whatever kind of days you want.
You can create whatever kind of days you want.
Studies in psychology showed that if you lock people away and had them set up their own cycles, that their day is typically 25 hours.
Really?
25 and a half.
That's why you never quite feel right.
Like the day is always a little bit ahead of you.
Yeah.
It's because you really want a 25-hour day. You need an extra hour.
You need an extra hour.
You need an extra couple hours.
And I thought I was just hungover.
an extra couple hours.
And I thought I was just hungover.
If light can't escape a black hole,
how would time be affected inside the black hole?
So now you got a force that is stronger,
that gravity is stronger than light itself.
As you fall into a black hole,
time ticks more slowly for you.
And you look out to the rest of the universe
and the rest of the universe goes by quickly.
In fact, as you descend to that cosmic abyss,
moments go by for you,
and trillions of years go by for the universe itself.
You will outlive the universe in your descent
to the center of a black hole.
Is the universe necessary for time to exist?
For example, was time present
within whatever came before the universe? Time, to exist? For example, was time present within whatever came
before the universe?
Time, as we have defined it, exists
only within this universe. If we go outside
of our universe, we'll have to think up
something else to keep track of things.
Maybe there's some meta-time that we
can think of, just the way we can think of
a multiverse, a word bigger
than the word universe itself. Maybe we are
longing for that word, such as word universe itself, maybe we are longing for
that word, such as metatime, that can accommodate our measuring needs when we exit this universe
in which we're born.
Welcome back to StarTalk Radio.
We're wrapping up our Season 4 Cosmic Queries Time Capsule Show with the episode on viruses and pandemics.
Journalist Lori Garrett joined comedian Chuck Nice and me to answer your burning questions on SARS, HIV, and other spreading diseases.
Chris's point, of course, is if we can make viruses that we control that are sort of machines but are small like viruses, we can infect you with something that we've manufactured in the lab.
Well, there is nanotech that is targeting disease.
And there is a lot of talk about…
That would be nanobots for good.
Yes.
The positive force of Marvel Comics or what have you.
Yes, the positive force of Marvel Comics or what have you.
These nano agents, which are still very much in the, I would say, the front end of the research process,
it is imagined would target, for example, killing cancer cells.
So they would recognize something on the surface of the cell that said, I'm a cancer cell, and then in and and kill it with a poison or what have you
but in the hands of the diabolical evil genius well the question really is to ask is there a way
to make a nanobot self-reproducing if a nanobot life would the way it's a virus if a nanobot
could be self-reproducing then indeed indeed you could have an out-of-control infectious problem.
Because it would have to replicate itself in order for that to happen.
Yes.
Like a virus would do.
Like a virus.
The other thing that's going on now is that we have this dichotomy of purpose where people in public health want to know what's going on with viruses in the natural world.
So we're ready and we make our countermeasures our vaccines and what have you but on the other hand there's a
lot of folks that say well the best way to answer that question is to do man-made evolution let's
direct the evolution of viruses in the lab manipulate them turn them into monster viruses
and see you know what does it take to be a monster virus so um last year
two different you were scaring the crap out of me well last year two different teams one in
wisconsin and one in rotterdam um indeed made a super killer form of flu in the lab and a whole
lot of people said why in the world would you do such a thing yes and those are now sitting in
freezers right we kept them last month not to
be outdone by americans because you know they don't want to be outdone by americans with anything
the chinese a lab in harbin made 127 man-made flu viruses of which five readily spread in the air
between guinea pigs and killed them oh my god so this is the new cusp that we're on is oh we're
trying to do it for good.
We're trying to see in advance what nature might do.
But in the process, you're putting in a freezer Armageddon.
And people were afraid of physicists.
The biologists are plum crazy.
You are not lying, man.
Oh, my God.
I'll take an atom bomb any day over this.
Yeah, I got to tell you, in the fraternity of science,
you guys are animal house.
Well, if you don't like that,
check this out.
No, stop there.
No, no, no, no.
You got something worse than that?
Wait, wait, there's more.
You got 20 seconds, go.
Post-synthetic biology.
There's a competition called iGEM.
In order to compete,
high school students and college students
have to make a novel,
not pre-existing microorganism. In 2012, there were 248 competing teams, meaning 248 previously
non-existent microbes were made by high school and college students.
That's the end.
That's the end.
It's the end of the world right here is what you just told us.
What do you think is the most interesting historical plague or epidemic viral or otherwise
and why is it so fascinating plague it completely reshaped europe forever the politics the the
culture the the status of the church the okay which play had many outbreaks which one it's
14th century the big one got the black black plague. The black plague. Black death. Black death. Okay. Why's it got to be a black death?
Chuck, say that for another show, Chuck.
People's skin turn black.
Okay.
Yeah, all of a sudden that's a bad thing.
Okay.
Chuck.
In the case of viruses and vaccines, if a disease gets eradicated, okay, will future
generations still have to get vaccinated for those diseases?
No.
None.
Nice.
Good.
Okay.
She's getting the hang of it.
She's good.
She's good.
All right.
So once it's gone, it's all gone.
AKA smallpox.
We don't vaccinate anymore.
Could pathogens be spread in the atmosphere?
A recent study done by Georgia Tech researchers found that E. coli amongst a great deal of bacteria that formed a sort of bacterial sphere in the upper atmosphere.
Yes, we now have proof that pathogens, particularly sporulating ones, can spread in clouds and rain down in locations far away.
Oh, man, that is one time you do not want to make it rain.
Do you stay inside when that happens?
Well, you don't know it's coming and you don't know it's you don't know for nothing what is the minimum size of a population
that can support a viral infection so in other words uh for for the virus itself to to be able
to continue on its life what's the minimum number of people you need in a community so it can spread and continue to be virulent?
In theory, one, if it's a slow-growing microbe and a slow-replicating one, for the duration of your life, you can be the host for it.
Gotcha.
So in theory, I could be a virus of one, like the army.
You got it.
Nice.
Virus of one.
Has the link between a chicken virus
and obesity been proven?
First time I ever heard
there was a link between
a chicken virus and obesity.
I think by chicken virus,
he means like a whole chicken
and eating one in a sitting.
You've been listening to StarTalk Radio,
brought to you in part by a grant
from the National Science Foundation.
As always, I bid you to keep looking up. you you you you you you you you you you you you you you you you you you you you you you you you you you you you you you you you you you you you you you To keep looking up.