Lex Fridman Podcast - Michio Kaku: Future of Humans, Aliens, Space Travel & Physics
Episode Date: October 22, 2019Michio Kaku is a theoretical physicist, futurist, and professor at the City College of New York. He is the author of many fascinating books on the nature of our reality and the future of our civilizat...ion. This conversation is part of the Artificial Intelligence podcast. If you would like to get more information about this podcast go to https://lexfridman.com/ai or connect with @lexfridman on Twitter, LinkedIn, Facebook, Medium, or YouTube where you can watch the video versions of these conversations. If you enjoy the podcast, please rate it 5 stars on Apple Podcasts or support it on Patreon. Here's the outline with timestamps for this episode (on some players you can click on the timestamp to jump to that point in the episode): 00:00 - Introduction 01:14 - Contact with Aliens in the 21st century 06:36 - Multiverse and Nirvana 09:46 - String Theory 11:07 - Einstein's God 15:01 - Would aliens hurt us? 17:34 - What would aliens look like? 22:13 - Brain-machine interfaces 27:35 - Existential risk from AI 30:22 - Digital immortality 34:02 - Biological immortality 37:42 - Does mortality give meaning? 43:42 - String theory 47:16 - Universe as a computer and a simulation 53:16 - First human on Mars
Transcript
Discussion (0)
The following is a conversation with Michio Kaku.
He's a theoretical physicist, futurist, and professor at the City College of New York.
He's the author of many fascinating books that explore the nature of our reality and the
future of our civilization.
They include Einstein's Cosmos, Physics of the Impossible, Future of the Mind, Parallel
Worlds, and his latest, the Future of Humanity, terraforming Mars into stellar travel, immortality, and our destiny beyond Earth.
I think it's beautiful and important when a scientific mind can fearlessly
explore through conversation subjects just outside of our understanding.
That to me is where artificial intelligence is today, just outside of our understanding.
A place we have to reach for if we are to uncover the mysteries of the human mind and build
human level and superhuman level AI systems that transform our world for the better.
This is the Artificial Intelligence Podcast.
If you enjoy it, subscribe on YouTube, give it 5 stars and iTunes, support it on Patreon,
or simply connect with me on
Twitter. Alex Friedman spelled F-R-I-D-M-A-N. And now, here's my conversation with Michio Kaku. You've mentioned that we just might make contact with aliens or at least hear from them within
this century.
Can you elaborate on your intuition behind that optimism?
Well, this is pure speculation, of course, of course, but given the fact that we've already identified
4,000 exoplanets orbiting other stars, and we have a census of the Milky Way galaxy for the first
time. We know that on average, every single star on average has a planet going around it,
and about one-fifth or so of them have Earth-sized planets going around them.
So just do the math. We're talking about out of a hundred billion stars in the Milky Way galaxy.
We're talking about billions of potential Earth-sized planets.
And to believe that we're the only one is, I think, rather ridiculous given the odds.
And how many galaxies are there within sight of the Hubble Space Telescope?
There are about 100 billion galaxies. So do the math. How many stars are there in the visible universe?
100 billion galaxies times 100 billion stars per galaxy, we're talking about
a number beyond human imagination.
And to believe that we're the only ones, I think, is rather ridiculous.
So you've talked about different types of type 0, 1, 2, 3, 4, and 5, even of the Kardashian
scale of the different kind of civilizations.
What do you think it takes,
if it is indeed a ridiculous notion
that we're alone in the universe?
What do you think it takes to reach out,
first to reach out through communication and connect?
Well, first of all, we have to understand the level
of sophistication of an alien life form.
If we may contact with them, I think in this century, we'll probably pick up signals, signals
from an extraterrestrial civilization.
We'll pick up their I love Lucy and their leave it to beaver.
Just ordinary day-to-day transmissions that they emit.
And the first thing we want to do is to a decipher their language, of
course, but be figure out at what level they are advanced on the cardi-ship scale. I'm a physicist.
We rank things by two parameters, energy and information. That's how we rank black holes. That's how we rank stars. That's how we rank civilizations
in out of space. So a type one civilization is capable of harnessing planetary power. They
control the weather, for example, earthquakes, volcanoes. They can modify the course of geological events, sort of like flash Gordon or Buck Rogers. Type 2 would be stellar. They play
with stars, entire stars. They use the entire energy output of a star, sort of like Star Trek.
The Federation of Planets have colonized the nearby stars. So a type two would be somewhat similar to Star Trek. Type three would be Galactic,
they roamed the Galactic Space lanes, and type three would be like Star Wars, a Galactic civilization.
The one day I was giving this talk in London at the planetarium there, and the little boy comes up
to me and he says, Professor, you're wrong.
You're wrong, there's type four.
And I told them, look kid, there are planets, stars,
and galaxies, that's it folks.
And he kept persisting and saying, no, there's type four.
The power of the continuum.
And I thought about it for a moment.
And I said to myself, is there
an extra galactic source of energy, the continuum of Star Trek? And the answer is yes. There could
be a type four. And that's dark energy. We now know that 73% of the energy of the universe is dark energy. Dark matter represents maybe 23% or so,
and we only represent 4%.
We're the odd balls.
And so you begin to realize that,
yeah, they could be type four, maybe even type five.
So type four, you're saying being able to harness
sort of like dark energy,
something that permeates the entire universe.
So be able to plug into the entire universe as a source of energy. That's right. And
dark energy is the energy of the big bang. It's why the galaxies are being pushed
apart. It's the energy of nothing. The more nothing you have, the more dark
energy that's repulsive. And so the acceleration of the universe is accelerating because the more you have,
the more you can have. And that of course is by definition an exponential curve. It's called a
decider expansion. And that's the current state of the universe. And then type five. Would that be,
would that be able to seek energy sources
somehow outside of our universe?
And how it produces that idea?
Yeah, time five will be the multiverse.
Multiverse.
I'm a quantum physicist
and we quantum physicists don't believe
that the big bang happened once.
That would violate the Heisenberg Inserti principle.
And that means that there could be multiple bangs
happening all the time, even as we speak today,
universes are being created.
And that fits the data.
The inflationary universe is a quantum theory.
So there's a certain finite probability
that universes are being created all the time.
And for me, this is actually rather aesthetically pleasing,
because I was raised as a Presbyterian, but my parents were Buddhists, and there's two
diametrically opposed ideas about the universe. In Buddhism, there's only Nirvana. There's
no beginning, there's no end, there's only timelessness. But in Christianity there is the instant when God said, let there be life.
In other words, an instant of creation.
So I've had these two mutually exclusive ideas in my head,
and I now realize that it's possible to mel them into a single theory.
Either the universe had a beginning or it didn't, right?
Wrong.
You see, our universe had a beginning.
Our universe had an instant where somebody might have said,
let there be light, but there are other bubble universes
out there in a bubble bath of universes.
And that means that these universes are expanding
into a dimension beyond our three-dimensional
comprehension.
In other words, hyperspace.
In other words, 11-dimensional hyperspace.
So Nirvana would be this timeless 11-dimensional hyperspace where big bangs are happening all
the time.
So we can now combine two mutually exclusive theories of creation.
And Stephen Hawking, for example, even in his last book, even said that this is an argument
against the existence of God. He said there is no God because there was not enough time for God
to create the universe because the big bang happened in an instant of time, therefore there was no
time available for him to create the universe. But you see the multiverse idea means that there was
a time before time. And there are multiple times, each bubble has its own time. And so it means that
there could actually be a universe before the beginning of our universe.
So if you think of a bubble bath,
when two bubbles collide,
or when two bubbles vision to create a baby bubble,
that's called the Big Bang.
So the Big Bang is nothing but the collision of universes
or the budding of universes.
That's a beautiful picture of our incredibly mysterious
existence.
So is that humbling to you?
Exciting?
The idea of multiverse is I don't even know how to even begin to wrap my mind around.
Exciting for me, because what I do for a living is string theory.
That's my day job.
I get paid by the city of New York to work on string theory.
Yes.
And you see string theory is a multiverse theory.
So people say, first of all, what is string theory?
Yes.
String theory simply says that all the particles we see in nature, the electron, the proton,
and quarks, what have you, are nothing but vibrations on a musical string, on a tiny,
tiny little string.
You know, G. Robert Oppenheimer, the creator of the atomic bomb,
was so frustrated in the 1950s with all these subatomic particles
being created in our advanced measures that he announced.
He announced one day that the Nobel Prize in physics
should go to the physicist who does not discover a new particle that year.
Well, today we think
there's nothing but musical notes on these tiny little vibrating strings. So what is physics?
Physics is the harmonies you can write on vibrating strings. What is chemistry? Chemistry is the
melodies you can play on these strings. What is the universe? The universe is a symphony of strings. And then what is the
mind of God that Albert Einstein so eloquently wrote about for the last 30 years of his life?
The mind of God would be cosmic music resonating through a 11- dimensional hyperspace. So beautifully put, what do you think is the mind
of Einstein's God?
Do you think there's a why that we can entangle
from this universe of strings?
Why are we here?
What is the meaning of it all?
Well, Stephen Weinberg winner of the Nobel Prize,
once said that the more we learn about the
universe, the more we learn that it's pointless.
Well, I don't know.
I don't profess to understand the great secrets of the universe.
However, let me say two things about what the giants of physics have said about this question.
Einstein believed in two types of God. One was the God of the
Bible, the personal God. The God that answers prayers, walks on water, performs miracles,
smights the Philistines. That's the personal God that he didn't believe in. He believed in the God of Spinoza, the God of order, simplicity, harmony, beauty.
The universe could have been ugly.
The universe could have been messy, random, but it's gorgeous.
You realize that on a single sheet of paper, we can write on all the known laws of the
universe.
It's amazing on one sheet of paper.
Einstein's equation is one inch long. Strength theory is a lot longer and so it's a standard model,
but you could put all these equations on one sheet of paper.
It didn't have to be that way.
It could have been messy.
And so Einstein thought of himself as a young boy entering this huge library for the first time, being overwhelmed by the simplicity,
elegance, and beauty of this library,
but all he could do was read the first page of the first volume.
Well, that library is the universe,
with all sorts of mysterious magical things that we have yet to find.
And then Galileo was asked about this.
Galileo said that the purpose
of science, the purpose of science is to determine how the heavens go. The purpose of religion is to
determine how to go to heaven. So in other words, science is about natural law.
And religion is about ethics.
How to be a good person, how to go to heaven.
As long as we keep these two things apart, we're in great shape.
The problem occurs when people from the natural sciences begin to pontificate about ethics
and people from religion begin to pontificate about natural law.
That's where we get into big trouble.
You think they're fundamentally distinct morality and ethics and our idea of what is right and what is wrong.
That's something that's outside the reach of strength theory and physics.
That's right. If you talk to a squirrel about what is right and what is wrong,
there's no reference frame for a squirrel. And realize that aliens from out of space,
if they ever come visit us, they'll try to talk to us like we talk to squirrels in the forest.
But eventually, we get bored talking to the squirrels because they don't talk back to us.
Same thing with aliens from out of space.
They come down to earth.
They'll be curious about us to a degree.
But after a while, they just get bored because we have nothing to offer them.
So our sense of right and wrong, what does that mean compared to a squirrel's sense of
right and wrong. Now we of course do have an ethics that keeps civilizations
in line, enriches our life, and makes civilization possible. And I think that's a good thing,
but it's not mandated by a law of physics. So if aliens do, alien species work to make contact. Forgive me for staying on aliens for a bit longer.
Do you think they're more likely to be friendly to befriend us or to destroy us?
Well, I think for the most part, they'll pretty much ignore us. If you were dear in the forest,
who do you fear the most? Do you fear the hunter with his gigantic 16 gauge shotgun?
Or do you fear the guy with a briefcase and glasses?
Well, the guy with a briefcase could be a developer
about to basically flatten the entire forest,
destroying your livelihood.
So instinctively, you may be afraid of the hunter. But actually, the problem
with deers and the forest is that they should fear developers. Because developers look at
deer as simply getting in the way. I mean, in war the world, by H.G. Wells, the aliens
did not hate us. If you read the book, the aliens did not have evil intentions
toward homo sapiens.
No, we were in the way.
So I think we have to realize
that alien civilizations may view us
quite differently than in science fiction novels.
However, I personally believe,
and I cannot prove any of this,
I personally believe that they're probably going to be peaceful
because there's nothing that they want from our world. I mean, what are they going to take us? What are they going to take us for? Gold?
No, gold is a useless metal for the most part. It's silver, I mean, it's gold in color, but that only affects homo sapiens. Squirrels don't care about gold.
colored, but that only affects homo sapiens. Squirrels don't care about gold. And so gold is a rather useless element. Rare earths, maybe platinum based elements, rare earths for
their electronics. Yeah, maybe. But other than that, we have nothing to offer them. I mean,
think about it for a moment. People love Shakespeare, and they love the arts and poetry, but outside of the earth they mean
nothing, absolutely nothing. I mean when I write down an equation in string theory
I would hope that on the other side of the galaxy there's an alien writing down
that very same equation in different notation, but that alien on the other side
of the galaxy, Shakespeare, poetry,
Hemingway, it would be nothing to him or her or it.
When you think about entities that's out there, extraterrestrial, do you think they would naturally
look something that even is recognizable to us as life, or would they be radically different?
Well, how did we become intelligent? Basically, three things made us intelligent. One is our eyesight,
stereo eyesight. We have the eyes of a hunter, stereo vision, so we lock in on targets, and who is
smarter? Predators are prey. Predators are smarter than prey. They
have their eyes at the front of their face, like lions, tigers, while rabbits have eyes
to the side of their face. Why is that? Hunters have to zero win on the target. They have
to know how to ambush. They have to know how to hide, camouflage, sneak up,
stealth, deceit.
That takes a lot of intelligence.
Rabbis, all they have to do is run.
So that's the first criterion,
stereo eyesight of some sort.
Second is the thumb.
The opposable thumb of some sort could be a claw or a tentacle.
So a hand-eye coordination. Hand-eye coordination is the way we manipulate the environment.
And then three, language. Because, you know, mama bear never tells baby bear to avoid the human
hunter. Bears just learn by themselves. They never hand out information from one generation to the
next. So these are the three basic ingredients of intelligence.
I cite of some sort, an opposable thumb
or a tentacle or a clob some sort, and language.
Now ask yourself a simple question.
How many animals have all three?
Just us.
It's just us.
I mean, the primates, they have a language. Yeah, they may get up to maybe 20 words,
but a baby learns a word a day, several words a day, a baby learns, and a typical adult knows about
almost 5,000 words. While the maximum number of words that you can teach a gorilla in any language, including their own language, is about 20 or so.
And so we see the difference in intelligence.
So when we meet aliens from out of space,
chances are they will have been descended
from predators of some sort that have some way
to manipulate the environment and communicate their knowledge
to the next generation.
That's it folks. So functionally, that would be similar.
That would be able to recognize them.
Well, not necessarily, because I think even with homo sapiens,
we are eventually going to perhaps become partyncybrenetic
and genetically enhanced.
Already, robots are getting smarter and smarter. become part cybernetic and genetically enhanced.
Already, robots are getting smarter and smarter. Right now, robots have the intelligence of a cockroach.
But in the coming years, our robots will be as smart as a mouse.
Then maybe as smart as a rabbit.
If we're lucky, maybe as smart as a cat or a dog.
And by the end of the century, who knows, for sure,
our robots will be probably as smart as a monkey.
Now, at that point, of course, they could be dangerous.
You see, monkeys are self-aware.
They know they are monkeys.
They may have a different agenda than us.
While dogs, dogs are confused.
You see, dogs think that we are a dog.
That we're the top dog.
They're the underdog.
That's why they whimper and follow us
and lick us all the time.
We're the top dog.
Monkeys have no illusion at all.
They know we are not monkeys. And so I think that in the future
we'll have to put a chip in their brain to shut them off once our robots have murderous thoughts.
But that's in a hundred years. In 200 years, the robots will be smart enough to remove that
fail-save chip in their brain and then watch out. At that point, I think, rather than compete
with our robots, we should merge with them. We should become part cybernetic. So I think
when we meet alien life from out of space, they may be genetically and cybernetically enhanced.
Genetically and cybernetically enhanced. Wow. So let's talk about that full range in the near term and 200 years from now.
How promising in the near term in your views, brain machine interfaces. So starting to allow computers to talk directly to the brains.
Elon Musk is working on that with neural link and there's other companies
working in this idea.
Do you see promise there?
Do you see hope for near-term impact?
Well, every technology has pluses and minuses.
Already, we can record memories.
I have a book, The Future of the Mind, or I detail some of these breakthroughs.
We can now record simple memories of mice and send these memories on the internet.
Eventually, we're gonna do this with primates
at Wake Forest University and also in Los Angeles.
And then after that, we'll have a memory chip
for Alzheimer's patients.
We'll test it out on Alzheimer's patients
because of course, when Alzheimer's patients
lose their memory, they wonder.
They create all sorts of havoc wandering around oblivious
to their surroundings.
And they'll have a chip.
They'll push the button and memories.
Memories will come flooding into their hippocampus
and the chip, telling them where they live and who they are.
And so a memory chip is definitely in the cards.
And I think this will eventually affect human civilization.
What is the future of the internet? The future of the internet is brain net.
Brain net is when we send emotions, feelings, sensations on the internet.
And we will telepathically communicate with other humans this way. This is going to affect
everything. Look at entertainment. Remember the silent movies Charlie Chaplin was very famous during
the era of silent movies but when the talkies came in nobody wanted to see Charlie Chaplin anymore
because he never talked in the movies and so a whole generation of actors lost their job.
And a new series of actors came in.
Next, we're going to have the movies replaced by Rainnet.
Because in the future, people will say,
who wants to see a screen with images?
That's it. Sound and image? That's called the movies.
It are entertainment industry.
This multi-billion dollar industry is based on screens with moving images.
And sound.
But what happens when emotions, feelings, sensations,
memories can be conveyed on the Internet.
It's going to change everything. Human relations will change because you'll be able to empathize and feel the suffering of other people.
We'll be able to communicate telepathically.
And this is coming.
You described the brainnet in the future of the mind.
This is an interesting concept.
Do you think, as you mentioned, entertainment,
but what kind of effect would it have on our personal relationships?
Hopefully it will deepen it. You realize that for most of human history, for over 90% of human history, we only knew maybe 20, 100 people. That's it folks. That was your tribe. That was everybody you knew in the universe was only maybe 50 or
100. With the coming of towns, of course, it expanded to a few thousand, with the coming
of the telephone. Of a sudden, you could reach thousands of people with a telephone,
and now with the internet, you can reach the entire population of the planet Earth.
So I think this is a normal progression.
And you think that kind of sort of connection
to the rest of the world, and then adding sensations
like being able to share telepathically motions and so on,
that would just further deepen our connection
to our fellow humans.
Yeah, that's right.
In fact, I disagree with many scientists on this question.
Most scientists would say that technology is neutral.
A double-edged sword, one sword, one side of the sword can cut against people.
The other side of the sword can cut against ignorance and disease.
I disagree. I think technology does have a moral direction.
Look at the internet. The internet spreads knowledge,
awareness, and that creates empowerment. People act on knowledge. When they begin to realize
that they don't have to live that way, they don't have to suffer under a dictatorship,
that there are other ways of living under freedom, then they begin to take power.
And that spreads democracy.
And democracies do not war with other democracies.
I'm a scientist, I believe in data.
So let's take a sheet of paper and write down every single war you had to learn since
you were in elementary school.
Every single war, hundreds of them, kings, queens,
emperors, dictators, all these wars were between kings,
queens, emperors, and dictators.
Never between two major democracies.
And so I think with a spread of this technology,
and which would accelerate with the coming of brainnet,
it means that, well, we will still have wars, wars of course, as politics by other means,
but there'll be less intense and less frequent.
Do you have worries of longer term existential risk from technology, from AI?
So I think that's a wonderful vision of a future where wars a distant memory.
But now there's another agent.
There's somebody else that's able to create conflict that's able to create harm AI systems.
So do you have worry about such AI systems?
Well, yes, that is an existential risk.
But again, I think an existential risk not for this
century.
I think our grandkids are going to have to confront this question as robots gradually
approach the intelligence of a dog, a cat, and finally that of a monkey.
However, I think we will digitize ourselves as well.
Not only are we going to merge with our technology, but also digitize our personality,
our memories, our feelings. You realize during the Middle Ages there was something called
dualism. Dualism meant that the soul was separate from the body. When the body died, the soul went
to heaven. That's dualism. Then in the 20th century neuroscience came in and and said, Bah, humbug. Every time we look at the brain, it's just neurons.
That's it folks, period, end of story,
bunch of neurons firing.
Now we're going back to dualism.
Now we realize that we can digitize human memories,
feelings, sensations, and create a digital copy of ourselves.
And that's called the Connect-On project.
Billions of dollars are now being spent to do not just the genome project of sequencing
the genes of our body, but the Connect-On project, which is to map the entire connections
of the human brain.
And even before then, already in Silicon Valley,
today, at this very moment, you can contact Silicon Valley
companies that are willing to digitize your relatives.
Because some people want to talk to their parents.
There are unresolved issues with their parents.
And one day, yes, firms will digitize people,
and you'll be able to talk to them
a reasonable
fact.
We leave a digital trail.
Our ancestors did not.
Our ancestors were lucky if they had one line, just one line in a church book saying the
date they were baptized and the date they died.
That's it.
That was their entire digital memory. I mean, their entire digital existence
summarized in just a few letters of the alphabet, a whole life. Now, we digitize everything. Every
time you sneeze, you digitize it. You put it on the internet. And so I think that we are going
to digitize ourselves and give us digital immortality.
We'll not only have biologic genetic immortality
of some sort, but also digital immortality.
And what are we gonna do with it?
I think we should send it into outer space.
If you digitize the human brain
and put it on a laser beam and shoot it to the moon,
you're on the moon in one second.
Shoot it to Mars, you're on Mars in 20 minutes.
Shoot it to Pluto, you're on Pluto in eight hours.
Think about it for a moment.
You can have breakfast in New York
and for a morning snack vacation on the moon,
then zap your way to Mars by noon time,
journey to the asteroid belt of the afternoon, and they
come back for dinner in New York at night, all in a day's work at the speed of light.
Now this means that you don't need booster rockets, you don't need weightlessness problems,
you don't need to worry about meteorites, and what's on the moon? On the moon, there is
a mainframe that downloads your laser beams
information. And where does it download the information into an avatar? And what does that
avatar look like? Anything you want. Think about it for a moment. You could be Superman, superwoman,
on the moon, on Mars, traveling throughout the universe at the speed of light
downloading your personality into any vehicle you want. Now let me stick my neck out. So for everything
I've been saying is well within the laws of physics. Well within the laws of physics. Now let me go
outside the laws of physics. Here we go. I think this already exists.
I think outside the Earth, there could be a super highway, a laser highway,
of laser-porting, with billions of souls of aliens zapping their way across the galaxy.
Now let me ask you a question.
Are we smart enough to determine whether such a thing exists or not?
No. We smart enough to determine whether such a thing exists or not.
No, this could exist right outside the orbit of the planet Earth, and we're too stupid in our technology
to even prove it or disprove it.
We would need the aliens on this laser super highway
to help us out, to send us a human interpretable signal. I mean, it ultimately boils down
to the language of communication. But that's an exciting possibility that actually the
sky is filled with aliens.
We could already be here. And we're just so oblivious that we're too stupid to know
it. See, they don't have to be an alien form with little green men.
They could be in any form they want
in an avatar of their creation.
Well, in fact, they could very well be,
they could even look like us.
Exactly.
They could never know.
One of us could be an alien.
You know, in a zoo, did you know that
we sometimes have zookeepers that imitate animals?
We create a fake animal and we put it in
so that the animal is not afraid of this fake animal.
And of course these animals brains,
their brain is about as big as a walnut.
They accept these dummies as if they were real.
So when alien civilization in out of space
was say, oh yeah, human brains are so tiny,
we could put a dummy on their world, an avatar, and they'd never know it.
That would be an entertaining thing to watch from the alien perspective.
So you kind of implied that with the digital form of our being, but also biologically, do
you think one day technology will allow individual human beings to become, besides just through the ability to digitize our essence.
Yeah, I think that artificial intelligence will give us the key to genetic immortality.
You see, in the coming decades, everyone's going to have their gene sequence.
We'll have billions of genomes of old people, billions of genomes of young people.
And what are we going to do with it?
We're going to run it through an AI machine, which has pattern recognition, to look for the age
genes. In other words, the fountain of youth that emperors kings and queens lusted over,
over the fountain of youth will be found by artificial intelligence. Artificial intelligence will identify where these
age genes are located.
First of all, what is aging?
We now know what aging is.
Aging is the buildup of errors.
That's all aging is.
The buildup of genetic errors.
This means that cells eventually become slower,
sluggish, they will want to senescence, and they die.
In fact, that's why we die. We die because of the build-up of mistakes in our genome, in our cellular activity.
But you see in the future, we'll be able to fix those genes with CRISPR-type technologies,
and perhaps even live forever. So let me ask you a question.
Where does aging take place in a car?
Given a car, where does aging take place?
Wow.
It's obvious, the engine, right?
A, that's where you have a lot of moving parts.
B, that's where you have combustion.
Well, where in the cell do we have combustion?
The mitochondria.
We know no where aging takes place.
And if we cure many of the mistakes that build up in the mitochondria of the cell, we
could become immortal.
Let me ask you, if you yourself could become immortal, would you?
Damn straight.
No, I think about it for a while because of course it depends on how you become immortal.
You know, there's a famous myth of tithanas.
It turns out that years ago in the Greeks mythology, there was the saga of tithanas and
aurora.
Aurora was the goddess of the dawn and she fell in love with a mortal, a human called tithanas and aurora. Aurora was the goddess of the dawn,
and she fell in love with a mortal,
a human called tithanas.
And so aurora begged Zeus to grant her
the gift of immortality to give to her lover.
So Zeus took pity on aurora and made tithanas immortal.
But you see, aurora made a mistake. A huge mistake.
She asked for immortality, but she forgot to ask for eternal youth.
So, poor tithinus got older and older and older every year decrepit, a bag of bones,
every year decrepit a bag of bones, but he could never die.
Never die. Body of life is important.
So I think immortality is a great idea as long as you also
have immortal youth as well.
Now I personally believe and I cannot prove this,
but I personally believe that our grandkids may have the option
of reaching the age of 30 and then stopping.
They may like being age 30, as you have wisdom, you have all the benefits of age and maturity,
and you still live forever with a healthy body.
Our descendants may like being 30 for several centuries.
Is there an aspect of human existence that is meaning for only because remortal?
Well Every waking moment we don't think about it this way, but every waking moment actually
We are aware of our death and our mortality. Yes. Think about it for a moment when you go to college
You realize that you are in a period of time where soon you will reach middle age and have a career.
And after that you'll retire and then you'll die.
And so even as a youth, even as a child, without even thinking about it, you are aware of your own death.
Because it sets limits to your lifespan.
I got a graduate from high school. I got to graduate from college. Why? Because you're
going to die. Because unless you graduate from high school, unless you graduate from college, you're
not going to enter old age with enough money to retire and then die. And so, yeah, people think about
it unconsciously because it affects every aspect of your being. the fact that you go to high school, college,
get married, have kids, there's a clock,
a clock ticking even without your permission.
It gives a sense of urgency.
Do you, do you yourself,
I mean, there's so much excitement and passion
in the way you talk about physics
and we talk about technology in the future.
Do you yourself meditate on your own mortality? Do you think about this clock that's ticking?
Well, I try not to because it then begins to affect your behavior. You begin to alter your behavior to match your expectation of when you're going to die. So let's talk about youth and then let's talk about
death. Okay. When I interview scientists on radio, I often ask them, what made the difference?
How old were you? What changed your life? And they always say more or less the same thing.
You know, these are Nobel Prize winners, directors of major laboratories, very distinguished scientists.
They always say, when I was 10,
when I was 10 something happened,
it was a visit to the planetarium,
it was a telescope for Steven Weinberg,
winner of the Nobel Prize, it was the chemistry kit.
For Heinz Pagels, it was a visit to the planetarium.
For Isidoriabi, it was a visit to the planetarium. For Isidor Rabi, it was a book
about the planets. For Al-Baudinstein, it was a compass. Something happened, which gives
them this existential shock. Because you see, before the age of 10, everything is mommy
and daddy, mommy and dad. That's your universe, mommy and daddy. Around the age of 10, you
begin to wonder, what's beyond mommy and daddy? And that age of 10, you begin to wonder what's beyond mommy
and daddy. And that's when you have this epiphany. When you realize, oh my god, there's a
universe out there, a universe of discovery. And that sensation stays with you for the
rest of your life. You still remember that shock that you felt gazing at the universe.
And then you hit the greatest destroyer of scientists known to science.
The greatest destroyer of scientists known to science is junior high school.
When you hit junior high school folks it's all over. It's all over. Because in junior high school. When you hit junior high school folks, it's all over. It's all over.
Because in junior high school, people say, hey, stupid. I mean, you like that nerdy stop
and your friends, Shanyu, all of a sudden, people think you're a weirdo. And science is made boring.
Richard Feynman, the Nobel Prize winner, when he was a child,
his father would take him into the forest,
and the father would teach him everything about birds.
Why they're shaped the way they are,
they're wings, the coloration, the shape of their beak,
everything about birds.
So one day, it bullied comes up
to the future Nobel Prize winner and says,
hey, Dick, what's the name of that bird over there?
Well, he didn't know.
He knew everything about that bird,
except his name. So he said, I don't know.
And then the bully said, what's the matter, Dick? You stupid or something?
And then in that instant, he got it.
He got it.
He realized that for most people, science is giving names to birds.
That's what science is.
You know lots of names of obscure things.
Hey, people say you're smart, you're smart.
You know all the names of the dinosaurs.
You know all the names of the plants.
No, that's not science at all.
Science is about principles, concepts, physical pictures.
That's what science is all about.
My favorite quote from Einstein is that,
unless you can explain the theory to a child,
the theory is probably worthless. Meaning that all great
theories are not big words, all great theories are simple concepts, principles,
basic physical pictures. Relativity is all about clocks, meter sticks,
rocket ships, and locomotives. Newton's laws of gravity are all about balls and spinning wheels and things like that.
That's what physics and science is all about, not memorizing things.
And that stays with you for the rest of your life.
So even in old age, I've noticed that these scientists, when they sit back, they still
remember.
They still remember that flush, that flush of excitement they felt with that first telescope,
that first moment when they encountered the universe.
That keeps them going.
That keeps them going.
By the way, I should point out that when I was eight, something happened to me as well.
When I was eight years old, it was in all the papers that a great scientist had just died.
And they put a picture of his desk on the front page.
That's it.
Just a simple picture of the front page of the newspapers of his desk.
That desk had a book on it, which was opened.
And the caption said, more or less,
this is the unfinished manuscript
from the greatest scientists of our time.
So I said to myself, well, why couldn't you finish it?
What's so hard that you can't finish it
if you're a great scientist?
It's a homework problem, right?
You go home, you solve it, or you ask your mom, why couldn't you solve it? So to me,
this was a murder mystery. This was greater than any adventure story. I had to know why the
greatest scientists of our time couldn't finish something. And then over the years, I found out
that guy had a name, Albert Einstein, and that book was the theory of everything.
It was unfinished. Well, today I can read that book. I can see all the dead ends and false starts that he made.
And I began to realize that he lost his way because he didn't have a physical picture to guide him on the third try. On the first try,
he talked about clocks and lightning bolts and meter sticks, and that gave us special
relativity, which gave us the atomic bomb. The second great picture was gravity,
with balls rolling on curved surfaces, and that gave us the big bang.
Creation of the universe, black holes.
On the third try, he missed it.
He had no picture at all, the guide him.
In fact, as a quote I have where he said,
I'm still looking, I'm still looking for that picture.
He never found it.
Well, today we think that picture is strengthring theory. The String theory can unify gravity and this mysterious thing that
Einstein didn't like which is quantum mechanics or couldn't couldn't quite
pin down and make sense of. That's right. Mother Nature has two hands, a left hand
and a right hand. The left hand is a theory of the small, the right hand is a
theory of the big. The theory of the small is the quantum theory.
The theory of atoms and quarks.
The theory of the big is relativity.
The theory of black holes, big bangs.
The problem is, the left hand does not talk to the right hand.
They hate each other.
The left hand is based on discrete particles.
The right hand is based on discrete particles. The right hand is based on
flute smooth surfaces. How do you put these two things together into a single theory?
They hate each other. The greatest minds of our time, the greatest minds of our time,
worked on this problem and failed. Today, the only theory that has survived every challenge so far is string theory.
That doesn't mean string theory is correct.
It could very well be wrong, but right now is the only game in town.
Some people come up to me and say, Professor, I don't believe in string theory.
Give me an alternative.
And I tell them there is none.
Get used to it.
It's the best theory we got. It's the only theory we have. And I tell them there is none. Get used to it.
It's the best theory we got.
It's the only theory we have.
It's the only theory we have.
Do you see, you know, the strings kind of inspire a view as did atoms and particles and
quarks, but especially strings inspire a view of a universe as a kind of information processing system as a computer or sorts.
Do you see the universe in this way?
No.
Some people think in fact the whole universe is a computer of some sort.
Yes.
And they believe that perhaps everything therefore is a simulation.
Yes.
I don't think so.
I don't think that there is a super video game
where we are nothing but puppets dancing on the screen
and somebody hit the play button
and here we are talking about simulations.
No.
Even Newtonian mechanics says that the weather,
the simple weather is so complicated
with shillings upon shillings of atoms
that it cannot
be simulated in a finite amount of time.
In other words, the smallest object which can describe the weather and simulate the
weather is the weather itself.
The smallest object that can simulate a human is the human itself. And if you had quantum mechanics,
it becomes almost impossible to simulate it
with a conventional computer.
This quantum mechanics deals with all possible universes,
parallel universes, a multiverse of universes.
And so the calculation just spirals out of control.
Now, at so far, there's only one way where you might be able to argue that the universe
is a simulation, and this is still being debated by quantum physicists.
It turns out that if you throw the encyclopedia into a black hole, the information is not
lost.
Eventually, it winds up on the surface of the black hole.
Now the surface of the black hole. Now the surface of the black
hole is finite. In fact, you can calculate the maximum amount of information you can store
in a black hole. It's a finite number. It's a calculable number, believe it or not. Now,
if the universe for me not a black hole, which is the maximum universe you can conceive of, each universe, each black hole has a finite amount of information.
Therefore, ergo, the total amount of information in a universe is finite. This is mind-boggling.
This, I consider mind-boggling, that all possible universes are countable, and all possible
universes can be summarized in a number.
A number you can write on a sheet of paper,
all possible universes, and it's a finite number.
Now, it's huge. It's a number beyond human imagination.
It's a number based on what is called a plank length,
but it's a number.
And so if a computer could ever simulate that number,
then the universe would
be a simulation.
So theoretically, because it's, because the amount of information is finite, they're, well,
they're necessarily must be able to exist a computer.
It's just from an engineering perspective, maybe impossible to build.
Yes.
So no computer can build a universe capable of simulating the entire universe except the universe itself. So that's your intuition that our universe is very efficient. And so there's no shortcuts.
Right. Two reasons why I believe the universe is not a simulation. First, the calculation numbers are just incredible. No finite, the, uh, touring machine can simulate the universe. And second,
why would any super intelligent being simulate humans?
If you think about it, most humans are kind of stupid.
I mean, we do all sorts of crazy stupid things, right?
And we call it art. We call it humor.
We call it human civilization.
So why should an advanced civilization go
through all that effort just to simulate satin night life? Well, that's a funny idea,
but it's also, do you think it's possible that the act of creation cannot anticipate humans?
You simply set the initial conditions and set a bunch of physical laws and just for the fun
of it, see what happens.
You'll launch the thing, so you're not necessarily simulating everything. You're not
simulating every little bit in the sense that you could predict what's going to happen,
but you set the initial conditions, set the laws, and see what kind of fun stuff happens.
Well, in some sense, that's how life got started. In the 1950s, Stanley did what is called a Miller experiment.
He put a bunch of hydrogen gas, methane, toxic gases
with liquid and a spark in a small glass beaker.
And then he just walked away for a few weeks,
came back a few weeks later and bingo out of nothing
in chaos came amino acids. If he had left it there for a few years, he might have gotten
protein, protein molecules for free. That's probably how life got started as a accident.
And if he had left it there for perhaps a few million years, DNA might have formed in that
beaker.
And so we think that, yeah, DNA, life, all that could have been an accident if you wait
long enough.
And remember our universe is roughly 13.8 billion years old.
That's plenty of time for lots of random things to happen, including life itself.
Yeah, we could be just a beautiful little random moment. And there's could be nearly
infinite number of those throughout the history of the universe. Many creatures like us.
We perhaps are not the epitome of what the universe is created for.
Thank God. Let's hope not. Just look around.
Look to your left, look to your right.
When do you think the first human will step foot on Mars?
I think it's a good chance in the 2030s that we will be on Mars.
In fact, there's no physics reason while we can't do it.
It's an engineering problem.
It's a very difficult and dangerous engineering problem,
but it is an engineering problem.
And in my book Future of Humanity,
I even speculate beyond that,
that by the end of the century,
we'll probably have the first starships.
The first starships will not look like the enterprise at all.
There'll probably be small computer chips
that are fired by laser beams with parachutes.
And like what Stephen Hawking advocated,
the breakthrough star shot program could send chips.
Chips to the nearby stars,
traveling at 20% the speed of light,
reaching Alpha Centauri in about 20 years time. Beyond that,
we should have fusion power. Fusion power is, in some sense, one of the ultimate sources of energy,
but it's unstable. And we don't have fusion power today. Now, why is that? First of all,
stars form almost for free. You get a bunch of gas large enough,
it becomes a star. I mean, you wouldn't even have to do anything to it and it becomes a star.
Why is fusion so difficult to put on the earth? Because in outer space, stars are monopoles.
They are pole, single poles that are spherically symmetric, and it's very easy to get spherically
symmetric configurations of gas to compress into a star.
It just happens natural by itself.
The problem is magnetism is bipolar.
You have a North Pole and a soft pole.
It is like trying to squeeze a long balloon.
Take a long balloon and try to squeeze it.
You squeeze one side and it bolted out the other side. Well, that's the
problem with fusion machines. We use magnetism with an earth pole and a south pole to squeeze gas
and all sorts of anomalies and horrible configurations can take place because we're not squeezing
something uniformly like in a star. Stars in some sense are for free. Fusion on the earth is very difficult.
But I think it's inevitable and it'll eventually give us unlimited power from sea water.
So sea water will be the ultimate source of energy for the planet Earth.
Why? What's the situation there?
Because we'll extract hydrogen from seaater, burn hydrogen in the fusion reactor
to give us unlimited energy without the meltdown,
without the nuclear waste.
Why do we have meltdowns?
We have meltdowns because in the fusion reactors,
every time you split the uranium atom,
you get nuclear waste.
Tons of it, 30 tons of nuclear waste per reactor,
per year.
And it's hot.
It's hot for thousands, millions of years.
That's why we have meltdowns.
But you see the waste product of a fusion reactor
is helium gas.
Helium gas is actually commercially valuable.
You can make money selling helium gas.
And so the waste product of a fusion reactor is helium,
not nuclear waste that we find in
a commercial fission plant.
And that controlling, mastering and controlling fusion allows us to convert us into type
one, I guess, civilization, right?
Yeah, probably the backbone of a type one civilization will be fusion power.
We by the way are type zero.
We don't even rate on this scale.
We get energy from dead plants for God's sake, oil and coal. But we are about 100 years from
being type one. Get a calculator. In fact, Carl Sagan calculated that we are about 0.7
fairly close to a 1.0. For example, what is the internet? The internet is the beginning of the first
Type 1 technology to enter into our century. The first planetary technology is the internet.
What is the language of Type 1? The internet already, English and Mandarin Chinese are the most
dominant languages on the internet. And what about the culture?
We're seeing a type 1 sports, soccer, the Olympics,
a type 1 music, a youth culture, rock and roll, rap music.
Type 1 fashion, Gucci, Chanel,
a type 1 economy, the European Union, NAFTA, what have you.
So we're beginning to see the the beginnings of a type
one culture and a type one civilization. And inevitably it will spread beyond this planet.
You talked about sending a 20% the speed of light on a chip into Alpha Centauri,
but in a slightly nearer term, what do you think about the idea when we still have
to send biological or biological bodies, the colonization of planets, colonization of
Mars?
Do you see us becoming a two planet species ever or anytime soon?
Well, just remember the dinosaurs did not have a space program.
And that's why they're not here today.
How come there are no dinosaurs in this room today?
Because they didn't have a space program.
We do have a space program, which means that we have an insurance policy.
Now, I don't think we should bankrupt the earth or deplete the earth to go to Mars.
That's too expensive and not practical.
But we need a settlement.
A settlement on Mars in case something bad happens to the planet Earth.
And that means we have to terraform Mars.
Now the terraform Mars, if we get raised at temperature of Mars by 6 degrees, 6 degrees,
then the polar ice caps begin to melt, releasing water vapor.
Water vapor is the greenhouse gas.
It causes even more melting of the ice caps.
So it becomes a self-fulfilling prophecy.
It feeds on itself.
It becomes autocatalytic.
So once you hit six degrees,
rising of the temperature on Mars by six degrees,
it takes off.
We melt the polar ice caps and liquid water. rising of the temperature on Mars by 6 degrees, it takes off. And we multiple
rice gaps and liquid water once again flows in the rivers, the canals, the
channels, and the oceans of Mars. Mars once had an ocean we think about the size of
the United States. And so that is a possibility. Now, how do we get there? How do we
raise the temperature of Mars by six degrees?
Elon Musk would like to detonate hydrogen warheads
on the polar ice caps.
Yes.
Well, I'm not sure about that, because we don't know
that much about the effects of detonating hydrogen warheads
to melt the polar ice caps.
And who wants to glow in the dark at night,
reading the newspaper?
So I think there are other ways to do it with solar satellites.
You can have satellites orbiting Mars that beam sunlight onto the polar ice caps melting the polar ice caps.
Mars has plenty of water. It's just frozen.
I think you paint and inspiring in a wonderful picture of the future.
It's, I think, you've inspired and educated thousands of not-millions.
Meecho, it's been an honor. Thank you so much for talking to me today.
My pleasure. Thank you.