Daniel and Kelly’s Extraordinary Universe - What is the quantum internet?
Episode Date: June 17, 2025Daniel and Kelly strip away the hype and reveal the actual mind-blowing physics of the quantum internet.See omnystudio.com/listener for privacy information....
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If you want to talk about your sincere awe and wonder at the incredible physical
universe, I'm here for that. If you want to have cold water thrown over your dreams of space
colonization, Kelly is at your service. Today, we're going to flip that script a little bit. It's my
turn to be a wet blanket about overhyped technology. But along the way, you'll learn just how
amazing and weird our universe really is. No hype necessary. That's right. Today, we are
tackling physics buzzwords. Two of my favorites, actually, quantum, probably the most overused word
in pop-side journalism and the internet.
The classic would make anything sound more high-tech.
Internet of Things was supposed to make your toaster seem like something from the future, right?
So today we'll explore the science and the hype and the actual amazing, beautiful physics
behind a pair of buzzwords that have come together to make a recent splash in the news.
The Quantum Internet.
It's not the latest Ant-Man movie.
It's today's topic.
Welcome to Daniel and Kelly's extraordinary quantum universe.
Hello, I'm Kelly Wienersmith.
I study parasites and space.
And when we come up with quantum parasites, you all better be worried.
Hi, I'm Daniel.
I'm a particle physicist, and the only kind of parasite I want is a quantum one.
I don't want 2.72 tapeworms.
I want zero or one, preferably zero.
Oh, but you really don't know until you actually look, you know?
Until you put the scope down your digestive system.
You don't actually know if there's one in there or not.
That's true.
Schrodinger's tapeworm.
Oh, fantastic.
But now I have a real question for you.
Can you have a non-integer number of parasites?
Can they split in some weird way where you're like, hmm, I'm not really sure if that's another one.
I mean, you can have hard to count things.
So the way tapeworms work is they've got a head.
The head holds on to part of your.
body and then they form segments called proglottids and each proglotted makes its own sets of
eggs and sometimes the proglotid dissolves away and the eggs pass with your feces into the
environment other times a proglotid just pops off and passes with your feces and sometimes it'll look
like pieces of rice walking around in your feces and that's proglotted and so you can have you know
like pieces of the tapeworm that sort of like separate but are still moving but we usually count
how many tapeworms an organism has based on the number of heads that you find so that's
pretty straightforward.
So parasites are quantized.
There you go. Amazing. We went from quantum physics to parasites to poop in record time on the
podcast. That's what happens when you have a particle physicist and a parasitologist.
Yeah, but you're right. We got there pretty fast today. I'm having a good day. We're having a good day.
All right. And we are moving at the speed of information, trying to understand how the universe
works and sending it to you down the internet tubes. So there's a lot of misinformation out there
about parasites. And there's also a lot of misinformation out there about what the word quantum
means. So Daniel, today we're talking about quantum internet. Yeah, that's right. The latest word to have
quantum slapped in front of it. That's right. So today we're going to find out if that makes any sense
and if it's nearly as exciting as it sounds like it is on social media. And I'm not actually
that upset about the misinformation about quantum mechanics because it gives me an opportunity
to clarify how amazing the universe actually is. It's not really a wet blanket moment where you're
like, this sounded amazing, but it's really actually boring and nothing. It's like, this
sounded amazing, but the reality is even more cool.
I mean, I don't know why you got to sound so down on wet blanket people, but all right, fine.
I know you like to keep things upbeat around here.
Oh, I see.
You thought I was throwing a wet blanket on the wet blanket people?
Well, on me in particular.
I felt seen, but not in a good way.
I wasn't talking about you, but I think it says something.
He responded that way.
Yeah, you might be right.
All right.
So let's hear how our listeners responded.
I went out there and asked them if they knew anything about the quantum internet.
If you would like to contribute your thoughts for future episodes, we would love to hear from you.
Please write to us to questions at danielandkelly.org and you can join the choir.
In the meantime, think about it for a minute.
What is the quantum internet?
What does it mean?
Here's what our listeners had to say.
What is the quantum internet?
Now you're just making stuff up.
I have no idea, but I'm willing to learn.
I assume the quantum internet is the internet that joins together quantum computers.
Well, it sounds like the interconnected web of subatomic consciousness, or maybe where Ant Man hangs out.
The quantum internet is great and all, but every time I check my emails, they're both read and unread at the same time.
I would guess that it's internet that can travel the quantum realm to go faster in the speed of light.
I would assume that it is a network of computers that have all been based on quantum computing infrastructure and quantum computing nodes.
Maybe the quantum internet is to do with the internet being both truthful and untruthful at the same time.
I suspect mostly untruthful.
The quantum internet will know what you're searching for before you type it in.
If someone asks me what quantum internet is, I would say that that is the current structure of our internet.
It's either your email sent or not sent at the same time.
It's probably a place where astrophysicists and people who use quantum data exchange information.
I've never heard of the quantum internet before, but perhaps use of quantum computers on the internet.
I'm assuming it could do all sorts of neat things that we can't even imagine now.
It could just be an entire internet filled with cats in boxes, and I'm okay with that.
The quantum internet is a marketing term that's really just BS.
I can't say what the quantum internet is, but I can calculate various probabilities of what it might be.
The quantum internet is the name for the observation that any fact you find on the internet is equally likely to be true or untrue.
There were some really fantastic answers here, where your emails are both read and unread at the same time.
I love that.
I wonder if you get out of trouble if you're like, well, I know it was red and it was unread.
And so I answered it and didn't answer it.
But like, you know, move on.
Yeah.
As usual, people either knew the answer were widely off or hilarious.
I love this mixture.
I always look forward to listening to these.
There's so much fun.
Yep, I love you all.
Thanks, everybody.
This, I think, gave a really nice sort of overview of the various thoughts that people
have about quantum internet, what it does, or whether or not they have any idea at all what
it does. So let's just start from the beginning. Like, what is quantum internet?
Yeah, quantum internet is actually a real thing. It's not total nonsense. It's the idea that you
could take quantum computers, which we'll dig into in a minute, and you could connect them
in a quantum mechanical way. Not in the same way that we connect normal classical computers
that ship bits back and forth, but you could connect them using a
fancy technology called quantum teleportation, which helps you move quantum information between
one computer and another. And it makes sort of sense, like we used to develop computers and
then we networked all the computers together because that has obvious advantages, sharing
information, working in parallel, et cetera. And now we're developing quantum computers. And so you
might think, oh, it could be beneficial to connect quantum computers to each other because maybe
they could take over the world and enslave us. No, I mean, calculate our taxes faster or whatever
quantum computers are supposed to do. So the quantum internet really is two different ideas. It's
quantum computers connected together with quantum teleportation. Oh, that sounds very Star Trek-y. But so my
understanding of quantum computers is that we sort of are getting a handle on it, but this is not something that
you use like every day to solve normal problems. Yep. Connecting quantum computers, it feels like you're
jumping ahead five or six steps. Like shouldn't we get the computers to work first? Well, I don't know. I think we
should work on all the problems at the same time, right? It's not like we should finish physics before
we get started on biology because it's the foundation of everything, right? Right? I'm agreeing with you.
I mean, you need to be motivated. And how can you stay motivated if you're just doing physics? You need the good
stuff, too. You're right. We can't use the quantum internet without quantum computers, but we also don't
want to wait until quantum computers are a full-fledged thing before we start thinking about how to connect them.
And, you know, everybody out there is excited about different stuff. So there's a group out there that
recently made a splash because of their advance in quantum connection of quantum computers,
and we're going to talk about that in a minute. And that's why it's in the news. But I think it's a
good idea to push on all fronts simultaneously. All right, fair enough. There's enough people
excited about the question. You can work on more than one front. Can you give us a quick
explanation of what a quantum computer is? Right. So the quantum internet is a quantum connected
bunch of quantum computers. The core of that is a quantum computer. What is a quantum computer? And so
there's so much misunderstanding and misinformation about quantum computers, especially recently
because of Microsoft's results and Google's claims and clickbait writing articles.
Quantum computers are not computers that do infinite number of computations in parallel.
They are not computers that tap into the multiverse.
They are computers that use quantum mechanics to do calculations instead of using classical
physics or just normal bits, right?
So in a classical computer, the one that I'm using right now to record this podcast episode,
and the one that's inside your phone or whatever device you're listening on,
there's a bunch of bits.
There's zeros and ones.
And all of computation involves calculating new bits and flipping bits.
You know, for example, when you take a picture, it's stored in terms of those bits.
When you add two numbers, it expresses those numbers in binary form,
where every digit is a bit, a zero or a one, and it adds them in binary form.
So the lifeblood of normal computers are these bits that are zero or one.
And we use the rules of logic to build up a bunch of.
stuff that computers can do. But that's just one kind of computer, right? Technically, anything
is a computer. Like a baseball is a computer. It just calculates only one thing, like what a baseball
can do. The cool thing about digital computers, the ones we know and love, is that they're programmable.
We figured out a way to take advantage of this very basic operation and map into lots and lots
of really interesting problems. Cool, but there's some things that classical computers are
slow at. You know, just because you can map them into lots of things.
doesn't mean that they're very good at things, you know, like counting to a super high number.
It can take a while. Anybody who's like run a piece of code over massive data set knows it
can like take a day or something, even on fast computers. And so quantum computers say, well,
what if there's another way to do computation? Instead of starting from something like a zero or
one, let's start from a state that's more ambiguous, like a qubit. A qubit is something
that doesn't have to be zero or one. It can have a probability to be zero and a probability to be one.
And so there's like more fuzz there.
And the rules of quantum mechanics are different from the rules of digital logic.
And so that maps to a different set of problems that quantum computers can do quickly or do slowly.
Maybe this was when we were talking to Scott Aronson the other day.
He said something about how quantum computers are better when you want to solve quantumy problems or things like protein folding.
Like if I have a question about parasites, I wouldn't make a computer out of parasites.
Why does using qubits make it easier to solve those kinds of problems?
Well, actually, I disagree with you, Kelly.
I think you should build a parasite computer, and let me tell you why.
Okay.
You know, let's say you wanted to know what happens on a certain quantum process, right?
Well, one thing you could do is you could try to simulate that process on a classical computer.
You could, like, represent it abstractly using zeros and ones, and then encode the rules of quantum physics into that digital logic and run it.
It might be kind of slow.
Or you could just ask the quantum object itself.
You could just do the experiment, right?
Say, oh, I'm just going to ask the universe.
I'm going to put the quantum objects in that situation.
I'm going to see what happens.
And then behind the scenes, the universe is following those rules of quantum mechanics for you.
And the universe's computation is free and kind of infinitely fast.
And so in comparison, if you wanted to know, Kelly, like what happens if you drop a tapeworm
into a can of Coke, just drop the tapeworm into a can of Coke.
That's a parasite computer right there.
We think about computing sort of narrowly, like what can be done in Excel, but computing is really just like getting the answer to a question.
And sometimes building the system itself that you have a question about is the most natural way to get the answer.
Okay.
So one, I don't expect that Coke is going to be running any ads on our website for our podcast for the foreseeable future.
You don't think tapeworms like Coke?
What?
You think they prefer something else?
Are they Pepsi fans?
I was going to make a joke about Coke being no worse once a tapeworm is dropped in there.
But I'm just kidding.
I'm just kidding.
Wait, have you done that experiment?
Do you know the answer to that calculation?
I would never do something like that to a parasite.
Though I have dropped some in ethanol and formalin.
So then backing up to Scott's comment,
it's natural to calculate quantum things using a quantum computer
because it's simpler to express them.
It's likely to be fast.
Now, in principle, anything you can calculate on a quantum computer,
you can also calculate on a normal computer.
Why?
Because you can simulate a quantum computer on a normal computer, right?
Just design one in your,
symbolic logic and let it run and simulate the laws of quantum mechanics, it's going to be
slower. The same way, like, calculating exactly what happens to a baseball could be slower than
just throwing the baseball, right? Let the universe do the computation. So the thing they know about
quantum computers is that it's a different way to represent problems we might want to solve, and they're
fast or slow at different things than baseballs or tapeworms or normal digital computers. So they're
like a radically different way to do computation. And potentially, they're very powerful at some
problems. So, you know, there's some problems that we think classical computers are going to be
very, very bad at. For example, finding out if a number is prime. If I give you a number,
how do you know if it's prime? Like if I ask you, 97, is it prime? Well, technically, you have to
check all the factors that might go into it one at a time. And there's some clever ways to do it
to be a little bit more efficient, but it's slow. And as the number gets big, that stays slow.
And amazingly, there's a guy who figured out an algorithm to do that on quantum computers much more
rapidly than on digital computers. So that's an example of a kind of problem, which for weird
reasons, because of the way quantum bits come together and the way we can map that problem
to mathematical problems, there are some things that would happen faster on a quantum computer
than on digital computers. But there's a very small number of those problems. People think like,
oh, quantum computers can solve anything, you know, they can break into anything. And they're often
used as like the McGuffin on these action movies, right? Don't let the terrorists get the quantum computer
or they'll get your bank account.
In reality, cryptography is better protected
than is often described in those movies.
And nobody has a quantum computer
that's powerful enough really to do anything
more quickly than classical computers.
So quantum computers are a real thing.
They're awesome in the future.
And we have bigger quantum computers
with more bits.
They can maybe solve really interesting problems
that otherwise would be very slow
on normal computers.
But no, they're not proof
that the multiverse exists.
They can't do infinite computation in parallel.
And they're currently not really useful for anything.
Couple questions.
All right.
First, so you were talking about bits being zero and one, and you're like, so we're
going to use something a little fuzzier.
That to me doesn't necessarily seem like an easy way to get a better answer.
So are quantum computers, you said they're better for some questions.
Are they worse for a lot of other questions?
Oh, yeah.
Okay.
So they don't always beat classical computers.
No, no.
Okay, all right.
And then you said they're not necessarily computing in the multiverse.
Do all of the quantum computer people believe you?
Because I feel like I've heard some who are like,
maybe this does prove the existence of the multiverse.
Are you not teaching the controversy here, Daniel?
That's a fair question.
I don't know anybody who I take seriously in quantum mechanics
who thinks that quantum computers prove that the multiverse exists.
I mean, how would you even steal man that argument?
I think the argument is that quantum computers require superposition of multiple
states. You know, for example, like your baseball can only have one energy. But an electron,
maybe it has a probability to have two different energies. It could have this energy or the other
energy. Or maybe it has two possible spins. It can simultaneously be in two states. Or more accurately,
you can say you can have the probability to be in two states at the same time. This is something
weird that quantum objects can do. Quantum computation relies on this because the law of quantum
physics predicts what will happen to each of those probabilities. And we map our problems onto those
quantum physics and use the outcomes of those probabilities to get the answer. So it relies on
superpositions existing, but we've known superpositions exist for a long, long time. You know,
like we have obvious examples of quantum superposition, all the Bell's experiments about
quantum entanglement that we'll talk about, the interferometer experiment, the double slit experiment,
like we have proof that superposition is a real thing before quantum computers. So like,
I don't think because superposition is real, that means there's any strong argument that the
multiverse is real. So I'm 99.99.9.
percent sure that quantum computing folks would say that this is just hype.
Have you let the Marvel folks know?
There's a universe in which the Marvel folks have reached out to me for physics consulting,
but it's not this universe.
Oh, bummer.
Bummer.
All right, that might have been the best universe to live in.
But, okay, so we've wrapped our heads around quantum computers.
So let's take a break.
And when we get back, we're going to talk about quantum teleportation.
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All right, and we're back.
Daniel, in Star Trek, is quantum teleportation how they move people from one place to another?
You're going to ask me about the physics of something totally fictional.
I love that.
That reminds me of when I used to give presentations in elementary schools.
And my favorite part about that was always opening the floor to questions.
And I remember one day getting a question that totally stumped me.
And the question was, just very similar to your question, actually.
It was, hey, everyone, just a note.
While we were recording this episode, a minor earthquake hit Southern California.
And my office shook a little bit.
But we decided to keep that audio in the recording for the sake of transparency about life in California.
I just got an earthquake alert.
Oh.
Do you feel it?
Yeah, I'm like literally shaking.
Are you still shaking?
No, we're done.
Wow, that was cool.
Do you need to check in with anyone?
No, just run in the middle day in California.
Hmm.
Some kindergartner asked me, if lightsabers were real, would they be?
made of liquid nitrogen.
Wow.
Wow.
I don't even know how to answer that question.
Yeah, where do you start?
Here's a khyber crystal.
Like, you want to walk you through the physics of khyber crystals?
Like, I don't know.
Anyway, I don't know how they do it in Star Trek.
But teleportation is a really interesting question philosophically.
And you probably know that because every time we have a science fiction author on,
I ask them what they think teleportation means even.
Does teleportation mean like your actual bits disappear and appear somewhere else?
Like, these atoms are now there?
or is it enough to tear you apart and rebuild you out of different atoms with the same arrangement, right?
Is it like a cut and paste? Is it like an email? What's going on? What is required for teleportation anyway?
It's kind of a deep philosophical question. Where do you stand on that, Kelly?
Yeah, you're dead. Yeah. No, you die and you get brought back somewhere else. You couldn't get me in one of those.
But that's only because I think you're assuming that they get torn apart and rebuilt.
What if there was an actual teleportation device that took your actual atoms and appeared them,
somewhere else. Would you get into that? I would be the one millionth person in line for that.
Okay. That was a yes. I heard a yes for folks. We have it on the air. If you're in line in
front of me, Daniel, then I will give it a shot. I would like my ashes teleported into the
center of the sun. How about that? Oh, interesting. All right, quantum teleportation. Let's step out
of Star Trek and into the real world. How does quantum teleportation work? Right. So quantum
teleportation is arguably not teleportation. I mean, it depends, again, exactly what you mean
by teleportation in that sense. But quantum teleportation is a way to transmit a quantum state.
You know, there's a difficulty here, which is like, let's say I have a particle in some quantum
state. And by a quantum state, I mean like it has a probability to be this and a probability
to be that, right? Take an electron, for example, and say it can just have two states up or down.
So let's say I have an electron. And I've done some complicated things.
to it so that it has a 70% chance of being up and a 30% chance of being down.
Can you actually do that?
Like, you can tinker with the probability that it's up or down?
You can do lots of different stuff.
Yeah, you can construct an experiment so that electrons have whatever probability you want
of doing basically whatever.
Oh.
That's what experimentalists do.
Yeah, exactly.
Wow.
Force the universe to do something cool.
And so let's say that's like the outcome of your calculation or whatever.
Now, maybe you want that information somewhere else, right?
Maybe you want this quantum state to exist, not here in California, but in some quantum computer in Virginia, right?
Where you're going to use that as the basis of your next calculation, or I don't know, whatever your folks do in Virginia with quantum states.
I know that we don't get earthquake alerts.
Wow, too soon. Too soon, buddy.
I'm sorry.
No, it's fine.
And so if you want to copy a quantum state from here to there, it's a little tricky because if I interact with that electron, if I like,
it or if I touch it or if I put in a box, I risk collapsing its state.
The universe allows things to stay in superposition
till they interact with something that can't be in superposition,
like a classical object, like my eyeball or my detector, whatever,
and then the universe picks, okay, spin up or okay, spin down.
And that could be fine, but if what you want to do
is preserve the quantum superposition, not to collapse it
and to copy that information somewhere else,
then you do something called quantum teleportation.
So that's really what quantum teleportation.
really what quantum teleportation is, is it transmits a quantum state from one system to another
without collapsing it, which is pretty cool. I don't know if it really qualifies as teleportation.
Are you actually moving the electron from one place to another? You're not at all moving the
electron. You're moving the arrangement, the quantum state. And so I have an electron here in
California. You have an electron in Virginia. I want to get your electron in Virginia to have the same
quantum state as my electron. I'm not like putting it on a UPS truck and driving it across
the country. I could do that. That's no big deal. But if I just want to transmit the information,
the arrangement, the quantum state, that's what we call quantum teleportation. And some of the
folks I know in foundations of quantum mechanics really hate that name. They're like, why they call
it teleportation. Okay, I know why, because it sounds cool, but it's not really teleportation.
It's misleading. And so it's important to understand what it actually means. But it kind of makes
sense, right? Like if you have a network of quantum computers, one basic thing you're going to want
to do is take a quantum state from one and copy it over to another one so it can like,
continue the calculation or whatever. So whatever you call it, it's an important part of having
networked quantum computers. I feel like it's one of those darned if you do, darned if you don't
situations. You know, like you call it teleportation and now it's awesome and I want to hear more.
Or you could be like, oh, Jupiter's Rings or A, B, C, and D. And I know I keep using it as an example,
but like that is so boring. You've got to be kidding me. So trying to find the sweet spot for naming
these things is tough. What would you call Jupiter's Rings, Kelly? Well, I'm going to need
some time to think about that. I don't know. I'm sorry. You've been complaining about the name for
weeks weeks. You're right. Oh, man. Putting me on the spot. I'm just calling your bluff. That's all.
Yeah, you are calling my bluff. What's the name of the ring and Lord of the Rings?
Precious. That's what Gallum calls it. That's what Gallum calls it. Yeah. The official name is
something at Elvish, isn't it? Oh, yeah. Anyway, all right, focusing again. Okay, quantum teleportation.
We understand what that is now. And you said that we can connect an electron in California to an electron in
Virginia. How does that process work? Yeah. So to do that, we're going to have to use something
called quantum entanglement. So we're three layers deep now. Quantum internet requires quantum
computers connected by quantum teleportation, which rests on the principle of quantum entanglement.
All right. So now we're going to dig into what is quantum entanglement fundamentally, and then
we'll come back and explain how you use quantum entanglement to do quantum teleportation to connect
your quantum computers on the quantum internet and play quantum doom with your quantum friends.
Oh, nice, but that probably would be easier on a classical computer.
You can put Doom on anything, though, right?
The day they pour Doom to something, that's how you know it's a real computer.
Yep, amen.
All right, so what is quantum entanglement?
And this is, again, something you hear a lot about on the internet.
And I know people are confused about because I get lots of emails from people saying, like,
why can't you use quantum entanglement to transmit information faster than light?
And you can't.
And we'll talk about why that is.
But you should also understand that quantum teleportation is not faster than light.
It's slower than light transmission of quantum information.
But before we get to that, let's understand what is quantum entanglement.
Quantum entanglement has to do with the superpositions we talked about earlier, the probabilities for various outcomes.
So let's say we have, instead of just one particle that can be spin up or spin down, say we have two electrons in California.
Each one can be spin up or spin down.
So how many possible states can they be in?
Well, there's four.
There's plus plus, plus minus, minus, and minus.
minus right so there's four possible states cool and if you just like to scramble the electrons they
can be in any of those states with equal probability cool but let's say we've done something clever
we're an experimentalist and we've prepared these electrons in such a way that there's a constraint on them
like they have to have opposite spins and this isn't so hard to do if they come from some state that has
a total spin zero the universe conserves angular momentum and so when you create these two electrons
their spin has to add up to zero it's not so hard and so if you do that it means that
that only two of the states are possible,
the one that is plus minus or minus plus.
The plus plus state and the minus minus state
no longer allowed.
So we've crossed two of the states off the list.
And boom, those two particles are now entangled.
Why do we say they're entangled?
Because their fates are connected, right?
If one is plus, the other one is minus.
If one is minus, the other one's plus.
And this is not some mystical thing where like,
you force one particle to be minus
and it reaches out through the universe
and makes the other one plus.
It's just that you have a list of options
and that list is limited.
And in every possible outcome, they have the opposite spin.
I'm keeping track of like how complicated all of these steps are.
So you said it's pretty easy to get an electron that's entangled so that one is plus and one
is minus.
What does pretty easy mean?
Do you have to like go into the LHC after spending billions of dollars or is this
something that can like happen in a lab on a UC campus?
This happens all the time.
Like every time a photon turns into an electron and a positron.
on, those are entangled.
Like, it's constantly happening all of the time.
And it's not actually that hard to do in the lab.
The thing that's tricky to do in the lab and the thing that's important is separating
those two and maintaining their entanglement.
You create those particles.
They're entangled.
And it's a really cool state because it's not yet determined, right?
They could be plus minus or they could be minus plus.
But then you could separate the particles.
You can say, I'm going to take particle B and I'm going to drive it to Virginia.
I'm going to leave particle A in California.
they're still entangled, right?
And then if I measure particle A when it's in California and I get plus,
then I know instantly what particle B in Virginia has to be because they're entangled.
The thing that's hard is keeping them entangled.
Because to keep them entangled, you have to avoid them interacting with anything else.
Like these electrons, they like to interact with stuff.
You put them in a box, they'll interact with a box.
You put them on a truck, they'll interact with a truck.
So keeping these particles in that state while separating them
means isolating them from everything else.
else because if they touch or interact with anything else then they get entangled with that thing
or they get entangled with you and now you are part of that quantum entanglement state to do the
things that we want to do in a minute to transmit information we need them entangled with each other
and with nothing else and that's where the sort of quantum magic comes from right these two particles
are now really far apart they can be a kilometer apart a light year apart and they both maintain
the uncertainty of being in plus minus or minus plus then you measure one of them you get a minus boom the
one is a plus. You know it. It's gone from uncertain to certain. That's the incredible thing about
quantum entanglement, is that you can maintain the connection across distances. That's the non-local
part of quantum mechanics. Can we dig in a little bit more about how you make them not interact with
anything? Do you use like electric fields to hold them in the center of a box? Electric fields are
an interaction. Oh, man. Yeah, exactly. What do you do? It's very hard. I mean, the simplest way you
can think about it as a thought experiment. It's like you're out in space. You have a photon. It turns
into an electron and a positron. And they're going in opposite directions already naturally, right?
Like if it had a lot of energy, then that energy is going to get transmitted to those particles. They're
just going to fly apart. And so along the way, they're not going to interact with anything if it's
really empty. And so they'll get further and further apart and still stay entangled. So on Earth,
of course, it's much more complicated. And people have all sorts of tricks for keeping these things
separated and keeping them isolated. It's not easy. It depends a lot on the details of the
quantum system, exactly the particles. We can dig into that in a future episode. I think that's a
cool idea. But it's not easy, right? The particles like to interact with everything else and
to decoher. This quantum state is very, very fragile. All right. So that is really awesome.
You mentioned that this can't be used for faster than light communication. Could you dig into that
a little bit more? Yeah. It sounds like you should be able to use it for faster than like
communication because there is something non-local and instantaneous happening. Particle A is in California,
particle B is in Virginia. Both of them are maintaining their superposition. Both of them could still
be plus or still be minus. The entanglement just says they have to be opposite. Both of them could
still be plus or minus, right? I make a measurement in California. I get plus. I instantly know
that you would get a minus if you measured yours in Virginia. So there is some sort of instant
across space and time thing happening there, which is very, very cool. And it sounds like you should
be able to use that for faster than light communication. A lot of people write it and say,
well, what if Daniel measures his and Kelly is watching? And so she knows. And he has a series of
these things. And Daniel measures them at a certain time and Kelly is watching the pattern or
something. It feels like you should be able to maybe use that for faster than like communication.
The problem is if I measure mine in California and I get plus, I know that you're going to get a
minus, but you don't know that. The only thing you can do is look at your particle and measure it.
And you don't know if it's collapsed or not. You can't tell that it's collapsed. I know that
it's collapsed, but there's nothing about the particle itself that shows you that it's collapsed.
You can measure it and get a minus cool, but you don't know if you got a minus because I already
collapsed it or because it was not collapsed and you collapsed it. There's no like your particle
has been collapsed light that goes on. So there's no way to manipulate these things. And I also can't
change it. It's not like I can say, oh, I have a plus. I'm going to flip it to a minus to make
Kelly's go the opposite. And as soon as I've measured mine, I break the entanglement, right? It's
over. It's interactive with something. That was a one-time deal. So in science fiction novels where
they have like entangled particles and they put one on a ship and they take them to Alphusantari,
and then they can use it as the basis of some ansible technology where they do FTL communication.
Yeah, that's pure nonsense. It's fun. I'd love it, but it doesn't work. Okay, so it can't be
used for helpful communication, but does the bit flip at a rate that's faster than light? So you bring
them to opposite sides of the universe. Do they communicate faster than light? Great question. Yes,
but I wouldn't say bit flip. So the collapse is instantaneous, right? If I measure mine in California,
then instantaneously yours collapses faster than light. Okay. Wow. Yeah. And that's weird and that's
cool. And that's the thing about quantum mechanics that we call non-local. Right. There's something global
that's happening there.
And people who've heard of Bell's experiment,
Bell's experiment proves to us
that it's not like one particle was always plus
and the other one was always minus.
We just don't know it.
It means that this uncertainty is real,
that they really do maintain the possibility
of both outcomes until you do measure it.
Bell's experiment proved
that there's no hidden information there
that determines the outcome.
It really is uncertain.
Or at least, and this is the important bit,
it proved that there's no local hidden information.
Quantum mechanics has to be non-local in some way.
either it really is probabilistic and it maintains these probabilities and collapses
instantaneously across space time when one of them is measured so you should really think of
it as like not two particles but one big quantum state you collapse it anywhere the whole thing
collapses or there are some other crazy theories about global quantum information you know like
super determinism or whatever that we can get into another time but you know the way most people
think about it is that it does collapse instantaneously across space and time which is
crazy, but you can't use it to transmit information because you can't control it, right?
You can ask it, you can query it, you can collapse it.
I can't even tell whether you've collapsed or not, and you can't tell whether I've collapsed
it or not.
Okay, so it's not useful for faster than light communication, but it is useful for quantum
teleportation.
So after the break, let's jump back up a level to quantum teleportation and try to understand
that.
I'm Dr. Joy Harden-Bradford, and in session 421 of therapy for black girls, I sit down with Dr. Afea and Billy Shaka to explore how our hair connects to our identity, mental health, and the ways we heal.
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All right, we're back.
So we now have a firm understanding of quantum entanglement.
Maybe we have a firm understanding.
And then we have two quantum computers, and we want them to be able to communicate with quantum teleportation.
Yes.
Tell us some more about how that works.
Right. So remember the problem we want to solve is I have my electron.
It's in some state. Maybe it's like 70, 30 plus or minus or whatever.
And you have an electron in Virginia, and I want to put your electron in the same state as my electron, and I don't want to collapse it.
And I also don't want to put it in a truck and drive it across the country.
How do I get that quantum information without collapsing it and make your electron have it?
Right.
And so the way we do that is through quantum entanglement.
Because I can interact with my electron without collapsing it
if I use with another quantum particle.
So if I touch the electron, or if I poke it with something classical
that can't be in a superposition, it will collapse the electron.
But if I let that electron interact with some other quantum thing
that can be in a superposition, it'll get entangled with that quantum thing.
So I have my electron, it's in the special state.
I bring in another particle, and I have those two interact somehow,
and now they're entangled.
You have the particle we want to copy and some other particle entangled with it.
Now, if I planned ahead and had entangled this other particle with a third particle that we then sent to Virginia,
we'd be ready to do quantum teleportation.
So here's the setup.
I have the original source particle I want to copy and a pair of particles that are entangled with each other but separated.
One in California and one in Virginia.
I entangle my California particle with the source particle without breaking the entanglement,
because it's a quantum particle.
And so the entanglement just spreads.
It doesn't break like it would
if it interacted with a classical object
or with the whole environment.
So I have my California end
of our entangled particle pair.
And now I've entangled that
with the source particle I want to copy
and I can see what happens
to the California end of the entangled pair.
They can use the information
in that new special particle.
I can read that off
and send you some information.
I can email it to you
or I can send it to you
be a carrier pigeon or whatever.
some slower than light process because everything is slower than light.
I send you that information and there's a recipe for using that information to copy the state of my
particle onto your electron.
I'm telling you what you have to do to your end of the California-Virginia entangled pair
to make it a quantum copy of my original source particle.
So to summarize, we entangle two particles, separate them while keeping them entangled,
entangle my California end of it with the source particle, read off some information about that
and send it to you so you know how to manipulate your Virginia end to make it a copy of my source
particle.
Okay, so you have something going on in your computer where you've got entangled cubits.
Yes.
And you send me an email with instructions for how to do that on my computer.
Yes, exactly.
And now my computer has the same entanglement stuff going on as your computer.
Yes, exactly.
There's a lot of little bits that we've skipped over because the math is a little complicated,
But the crucial thing to understand is that I've avoided collapsing my qubit by interacting with a quantum particle,
which now stores the information from it.
And I can extract that information from my quantum particle and send it to you so you can reverse the process.
If we have kept our entangled pair nicely entangled, you can prepare some quantum particle in that state,
have it interact with your electron, and then your electron will be in the same state as my original one was.
And so this is what quantum teleportation is.
It's a way to interact with the quantum objects, extract their information without collapsing
it, encode it into something that we can transmit across the world or whatever, and then reverse the process.
But when your quantum particle entangles with an electron in your computer, and then you look at what the quantum particle is doing so that you can tell my computer what to do,
when you look at your quantum particle, because it was entangled, doesn't it mess up the system?
It does actually mess up the system.
And so when you copy the state, it destroys the original state.
So the electron that I had in California is no longer going to be in that state that we both wanted.
So I extract that information.
I send it to you.
You use that to create the quantum state over there in Virginia, but there's a no cloning theorem that says that you can't extract that information without also destroying it.
But here we are extracting it in such a way that we can recreate the state in Virginia.
But yes, we've destroyed the state of the California electron.
So I'm not like just emailing you a PDF where like I also still have it.
I have to like shred that PDF somehow and send it to you so you can recreate it.
So the teleportation, and maybe this is where we discover that teleportation actually
wasn't a great term for this.
But okay, so the teleportation is actually just that you've used entanglement to figure out
what's happening with another electron.
You're sending me that information and you are like teleporting it by email, quote unquote.
And that's where the teleportation is happening.
Yeah, it's very equivalent to saying like, hey, Kelly, I built a really cool Lego house over here, and I'm going to send you the recipe. To do so, I need to like tear apart my Lego house so I can keep track of exactly how you're going to build it. Then I'm going to email you the recipe, and you guys are going to build the same Lego house over there. I had to destroy my Lego house to develop the recipe, and I just emailed it to you or send it to you via mail or whatever, but now you have the recipe to create exactly the same thing. And this is tricky only because these are quantum particles, and it's not easy to read them off and to
create these states, but this essentially is quantum teleportation. And I would kind of argue the
teleportation is not a terrible name for it. I mean, if the Star Trek teleporter is scanning you and
reading the quantum state of all your particles and then beaming that information to another machine
that can reverse that process, then yeah, that's kind of what we're talking about here. So everything
we've just talked about sounds pretty complicated. Can you give me some situations where you would
want to go through that process? Like, why would you create something in one computer, destroy it just
so you can create it on another computer.
Couldn't you just create it in the second computer from scratch without making it on the other one first?
Yeah, maybe, but perhaps it's the outcome of a very complicated, very expensive quantum computation.
You know, and like, let's say I have a quantum supercomputer and you ask me to do some calculation about your tapeworm simulation.
I don't know.
You have my attention.
I do it for you and I want to send you the result, right?
I want to use the quantum internet to send you this quantum answer to use.
your quantum computer from my quantum computer.
And yeah, you could recreate it,
but it might be really, really slow.
And so might as well just copy the answer
in the same way that your computer
can calculate your taxes much, much faster than you can,
and you might think, well, what do I need that?
I can just do it myself.
Yeah, but you might as well skip ahead and get the answer.
So in that way, the quantum information here
represents the results of a quantum computation,
which could be extraordinarily valuable, right?
And so you might wanna save that.
And people have thought about ways
to build super powerful quantum computers
by tying together,
quantum bits across the quantum cloud, right?
The way we make very powerful computers by spreading information and computation across
them.
You ask Amazon to do a complicated calculation.
It doesn't just run it on one computer.
It runs on 10, 50, 100, so that you get the answer faster.
In the same way, maybe you take a big quantum problem, you break it into pieces.
Each quantum computer does a piece of it, and then they want to send the answer back
to some central node, which puts it together to get the final answer.
That requires a quantum internet of quantum computers that can.
send quantum states back and forth to each other. And so that's why this is a stepping stone
to some future awesome, globally linked quantum computer. And so where are we now? Has somebody
recently done this quantum teleportation thing? Yeah, so people have been working on this for a while.
And the bit that we talked about the quantum entanglement and sending information usually requires
really specialized hardware. Keeping our two particles entangled is hard because we have to keep
them isolated from any classical object. And what happened recently is a lab at Northwestern in
Northern Chicago, managed to do quantum teleportation over normal fiber optics, right?
So usually, like, keeping that information pristine and clean is very, very hard, right?
You have specialized hardware to transmit this information.
It has to be just right.
But they were able to use fiber optic cables that were 30 kilometers long that already also
had normal internet traffic.
So, like, people randomly emailing and texting pictures of their cats and whatever.
And they were able to send this information to do quantum teleportation across this
noisy, totally standard fiber optic cable. And so that was the excitement recently about the
quantum internet is that we went from like, you need specialized, dedicated hardware to do it for a
single electron to like, oh no, we can do it over long distances using standard equipment that
already exists. But you're not sending entangled electrons through fiber optics. You're just
sending instructions through fiber optics that then set up the next computer on the other side. Is that
right? Yes, that's exactly right. Okay. Still totally.
awesome. I just wanted to make sure I was understanding. All right. Awesome. Yeah. And so this is
the first demonstration of quantum teleportation of entangled photons through busy optical
fibers that were also carrying conventional telecommunications traffic. So, you know, it brings us a step
closer. It's not like we have the quantum internet. It's not like you can log on right now to the
quantum internet and do your quantum taxes or anything like that. But, you know, this is an important
step forward in making this realistic because if we want to build a bunch of quantum computers and
connect them, it'd be nice if we could use standard equipment to do so and not have to build
a whole separate quantum internet. So it's cool. It's like very experimentally awesome.
Taxes are so complicated. It wouldn't surprise me if next year we need to be doing our taxes
on quantum computers, but I hope we're not getting there. Yeah, well, you should think about whether
you want to pay your taxes or not pay them or both. Whoa. Bum bum, bum. I know which one I'd rather
do. On the other hand, I really like my government services, so I feel complicated. And I like not
being in jail.
Yeah, me too.
Me too.
There's a lot of things that would be hard to do from jail.
Like this podcast.
Actually, that might be possible.
We'll find out maybe.
So the quantum internet is a real thing.
Quantum computers are real and they're awesome.
Not always in the way people say they are.
They're not the multiverse, but they are a new way to do computation.
And quantum teleportation is a real thing.
It's not faster than light.
It's not Star Trek.
But it is a way to transmit quantum states across vast distances, which is very cool.
bring them together and you get the quantum internet.
Quantum computers connected through quantum teleportation
to do massive quantum problem solving.
I think it's pretty cool.
The future is now.
And so I hope I didn't throw too much of a wet blanket on the quantum internet.
There is really a lot of awesome physics happening there.
And if one day we do have very powerful quantum computers,
they might be able to solve problems that do stump us today.
So I look forward to the first time an episode of this podcast is released on the quantum internet.
Well, you are now a member of the wet blanket.
blanket club, but it's going to be a while before you're president.
But I enjoyed spending this time with you.
Are you dictator for lives?
Is that how it works?
Yeah, yeah.
That's right.
And Zach is first husband of the dictator.
I'll start out as secretary to work my way up.
All right. Good luck.
All right.
Thanks, everybody for listening.
I hope we didn't entangle your minds, at least not too much.
Daniel and Kelly's Extraordinary Universe is produced by IHeart Radio.
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It can be as simple as talking to someone,
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You can go so much further.
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It's the heartache.
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I'm breaking down the players, the predictions, the pressure.
And, of course, the honey deuses, the signature.
cocktail of the U.S. Open. The U.S. Open has gotten to be a very wonderfully experiential sporting event.
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