Shawn Ryan Show - #219 Isaiah Taylor - CEO of Valar Atomics
Episode Date: July 17, 2025Isaiah Taylor is the audacious visionary behind Valar Atomics, an El Segundo based startup on a mission to reinvent atomic energy and fuel the future of mankind. Isaiah Taylor dropped out of high scho...ol at 16 to start a business and write software for the world's largest hedge fund, but his real obsession, inherited from his physicist great-grandfather, is nuclear energy. After ten years of obsessive research, Isaiah founded Valar Atomics with a radical plan to reboot the atomic age with mass-manufactured nuclear reactors which can make energy for AI and reverse combustion itself, turning atmospheric CO2 and water into carbon-neutral jet fuel and gasoline cheaper than drilling for oil. In one year, Valar Atomics has already built a 100,000-pound prototype reactor, the first step on their journey to making civilization beautiful again with abundant energy. Shawn Ryan Show Sponsors: https://americanfinancing.net/srs NMLS 182334, www.nmlsconsumeraccess.org https://aura.com/srs https://bubsnaturals.com – USE CODE SHAWN https://shawnlikesgold.com https://helixsleep.com/srs https://hexclad.com/srs https://ketone.com/srs Visit https://ketone.com/srs for 30% OFF your subscription order https://moinkbox.com/srs https://preparewithshawn.com https://patriotmobile.com/srs https://ROKA.com – USE CODE SRS https://shopify.com/srs https://betterhelp.com/srs This episode is sponsored. Give online therapy a try at betterhelp.com/srs and get on your way to being your best self. Isaiah Taylor Links: Valar Atomics - https://www.valaratomics.com X - https://x.com/isaiah_p_taylor Learn more about your ad choices. Visit podcastchoices.com/adchoices
Transcript
Discussion (0)
Isaiah Taylor, welcome to the show.
Thank you so much for having me.
It's an honor to be here in this incredibly inspiring room.
Lots of mementos in here that are sick.
So yeah, I'm excited to talk.
Thank you.
Thank you.
Yeah.
So I guess in the past six months we have really dove into the tech space. Yeah. And so we got connected through our mutual friend, Augustus Dorico, and the Rainmaker.
And when he was here, he was telling me all about what you were doing and that you guys were best friends.
Yep.
And I've been really interested in the power grid for a couple of years now.
It seems very weak.
Yes. There's a lot of work to do.
Yeah, and I think it was Scott Nolan that told me with the data centers and AI and everything
that by 2030, AI will be using the exact equivalent of the energy that we all use today in 10
years.
So all of our energy grid will be sucked up by 2030.
I think it's either all the energy grid will be sucked up by 2030 or we'll fall behind.
Right?
We'll fall behind on AI, which I think is unacceptable.
Right?
So this is a red hot screaming problem that has to be solved.
It's a national security issue.
So I think if you're working in energy, you're working on something really important.
So you're building basic, is it mini nuclear reactors? That's right,
so small modular reactors, the technical term, there's sort of three categories. Micro reactors
are 0 to 20 megawatts, SMR, small modular reactors are 20 to about 300, and then above 300 you're
just sort of the classic gigawatt scale large reactors. So we're kind of in the lower range
of SMRs.
Our first commercial unit will be around 25 megawatts electric.
What does that mean?
For somebody like me, that means nothing.
So yeah, it's a good question.
So a 25 megawatt electric unit will power a small town.
So if you want to do, if you want to power a big town, you put several of them next to
each other.
And this is a common strategy for nuclear.
Pretty much every nuclear site doesn't have just one nuclear unit on it has several.
Okay.
But we sort of take that to the logical conclusion and we say, we don't just build
normally it's like four, right?
So you have a site and you put like four units on it.
We want to have a site and put hundreds of units on it eventually.
To start off with, if you want to make a gigawatt, you know, put 40 down, right? So 40 units next to each other at 25 meg with, if you wanna make a gigawatt, put 40 down, right?
So 40 units next to each other
at 25 megawatt electric nameplate is a gigawatt of power.
Now you're powering like a big city, right?
Or you're powering several towns, several cities,
significant portion of the grid.
And when we look at AI demand,
we're looking at demand for data centers
as large as a gigawatt, which has never happened before.
This is like a brand new idea
of doing a data center that large.
Um, it's, we're super excited about it.
Wow.
What is a small town?
Would it give me a population size?
Yeah.
So I think, you know, that's probably going to a 25 megawatt electric unit.
It's going to be a town of, uh, probably like 15,000 people.
Okay.
Yeah.
And one could power that entire town.
Yeah.
That's amazing.
You know, just at breakfast this morning, I mean, just,
I love stories like this. You know, we weren't going to talk about your life story. We were
just going to go nuclear, but I just, man, just kudos to you. 26 years old, dropped out
of high school at 16, came from nothing, building, sounds like you had a great family that you're
very close with, but not a, I guess what I'm getting at is you didn't have a big trust fund or
anything like that to get started you did it on your own and and you are a
hell of an innovator and I just I didn't do it on my own but I certainly didn't
do it with a trust fund you know my parents are extremely supportive in just
always being there for me.
I talked to my dad basically every week on the phone,
we talked for a couple hours and he's always just believed
that I have what's necessary to fix large problems.
I'm not sure where he got that idea,
but he has always believed that.
And so I'm extremely grateful to him.
And then I've been helped by many other people, right?
Our investors at Valor couldn't do it without them., our investors at Valor couldn't do it without them.
My team members at Valor couldn't do it without them.
You know, previous companies that have started employees there.
So, you know, it's a, I'm standing on many, many shoulders at this point.
Not so much financially, but, but from other people.
But yeah, we, I grew up, you know, very poor.
We grew up on food stamps.
Most of growing up in various, you know,
rough places around the country.
And it was really just that my parents were, you know, my dad was, was, uh,
doing his best to provide for his family with the hand he had been dealt and was
extremely focused on us, on his kids.
Um, I like to say that my dad will, will, will prove to have been one of the greatest investors in history.
Wow.
Not because he invested money into a stock, but because he invested in his children.
And I do hope that Valor Atomics will be one of the most valuable companies of all time.
And my dad invested in me to be able to do that in terms of educating us and giving us work ethic,
especially giving us opportunities ethic, especially giving
us opportunities to get our hands dirty. Well, it sounds like you're well on your way.
So I hope so. Congratulations. Thank you. But everybody starts off with an introduction here.
So here we go. Isaiah Taylor, visionary behind Valor Atomics, an El Segundo based startup on a
mission to reinvent atomic energy and fuel the future of mankind.
A 26 year old self-taught innovator who dropped out of high school at age 16 to start a business and write software for the world's largest hedge fund.
A fierce advocate for nuclear renaissance, challenging outdated regulations and pushing for innovation to power AI industry and beyond.
Have a radical plan for mass producing small modular nuclear reactors to create carbon
neutral jet fuel and gasoline that is cheaper than drilling for oil.
In just one year, Valor Atomics has built a 100,000 pound prototype reactor, the first
step on their journey to making civilization beautiful again with abundant energy a
Midwestern or with Christian roots your great-grandfather worked on the Manhattan project giving you a personal connection to the atomic age Wow
Yeah, we can talk about Westminster to Westminster Confession of Faith if that's what we're getting at is also great
But no Midwestern, that's right. Yeah
but But so a couple of things to get through. One,
I have a Patreon account. It's a community,
it's a subscription account and they've been here with me since the beginning.
And so one of the things I do is I offer them each and every guest that comes on,
they get to ask a question. All right, and so this is from Ian Lane
Coming from a non-traditional path in a legacy tied to the Manhattan Project
How do you reconcile the historic weight of nuclear innovation with your vision of making it scalable clean and decentralized?
And what's the biggest?
Misconception people still have about nuclear energy today
So I think the first half of the question and thank you for the question Ian, right? and what's the biggest misconception people still have about nuclear energy today?
So I think the first half of the question, and thank you for the question, Ian, right?
Ian.
And thank you for supporting Sean, that's awesome.
So I think the first half of the question is like,
how do you go from a heavy centralized industry
to smaller, more mass manufactured,
lighter type of industry.
And then what was the second half of the question there?
And what's the biggest misconception people still have
about nuclear energy today?
Yeah, so the first half is like,
how do you go from this really big thing
to this small thing?
I would point out that this is something
that's happened before in other industries.
And the way that you do it is you start small
and you move very, very quickly
and learn as fast as you can with talented people.
So I think SpaceX is the great example here.
So the space industry before SpaceX
was really concentrated around these very large rockets
that were very expensive to build,
took a long time to build, did not launch very frequently.
And when SpaceX set out to create what they've created now,
they started much smaller, right?
They created the Falcon 1.
Falcon 1 was a tiny rocket.
It was really too small to make any sense or be economical,
but it taught them how to build rockets from scratch, right?
And it gave them a test platform
to test their construction methods and their engineering
and their motors and these sorts of things.
And then they got into the Falcon 9 and now they're building Starship.
So I think that we're going to follow a very similar track here
where over time I believe our reactors will slowly get larger,
but the first thing to do is you have to make sort of a minimum viable thing
that your team can build and can build quickly and learn lessons.
It's all about learning.
We really are having to reinvent nuclear. can build and can build quickly and learn lessons. It's all about learning.
We really are having to reinvent nuclear.
We can't just take the designs that we had in the 1960s.
Those designs don't work anymore for a few reasons.
It's not that they technologically don't work.
It's that they economically don't work.
So we don't have the tool chains and the labor to do massive engineering projects and massive
construction projects anymore.
This is something we were really, really good at in the 50s and 60s.
As a country, as a civilization, we were great at building large civil infrastructure.
Over time, we got worse at that, and we can talk about why, but the fact is we got worse
at that, and we got better at manufacturing.
If you're going to bring nuclear back today, I believe that the form factor of your reactor
should be reflective of that change,
where you're going toward more of smaller
manufactured things rather than these like
really big civil works projects.
So the short answer is like, you start small
and you move quickly and you learn fast with smart people.
And that's exactly what we're doing.
Interesting. Yeah. Interesting.
One more thing, everybody gets a gift. smart people and that's exactly what we're doing. Interesting. Yeah. Interesting.
One more thing.
Everybody gets a gift.
Nothing crazy.
Bujulance league gummy bears, legal in all 50 states.
Not that you have to worry about that living in LA.
I was gonna say, legal in all 50 states.
That makes it sound like it maybe shouldn't have been legal,
but are these like CBD or something like that?
No man, they're just kids. She's gummy bears.
Nice, but the regular gummy bears made in the USA.
Let's go.
Yeah.
All right.
I'm looking forward to that.
Some of the best junk food around.
My kids are going to enjoy that as well.
I have a gift for you.
I have two gifts for you.
So I have two hats which both say, make nuclear great again.
And this one still has a sticker on it.
So I take the sticker off.
Make nuclear great again. We have a black one and a white one. Nice. And both of them are for you. We're past Memorial Day and the president has
started wearing his white make America great again hat. So I made a white make
nuclear great again hat. Nice. Both of these are for you. Thank you. You have to sign this
white one. Let's do it. Yeah. So, yeah, that's awesome.
I was going to say great hat.
Thank you.
Thank you.
Well, now it's yours.
Thank you.
But, um, yeah, you know, like I said at breakfast, you were kind of talking about,
you know, how you met your wife and how you grew up.
And so I want to cover that stuff.
Cause I just, you know, you met your, not to get ahead of myself here, but you
met your wife in first grade.
I think that that's awesome, man. So let's start with your life story. You know, you met your, not to get ahead of myself here, but you met your wife in first grade.
I think that that's awesome, man.
So let's start with your life story.
Where'd you grow up?
So I grew up around the Midwest.
I was born in normal Illinois and my life has been very normal since then.
So that tracks.
And moved around the Midwest, moved to Colorado when I was, I believe around six.
And that's when I met Sophie.
So Sophie, my wife, we met in first grade,
we were in school together.
I don't know that we said many words to each other
in first grade, she was very shy,
but I thought she was cute.
And so we got to know each other the next few years,
went to church together,
and we were really just sort of a common denominator in each other's lives. years, went to church together, and we were really
just sort of a common denominator in each other's lives.
Both of us moved all over the country many times for various reasons, but we kept running
into each other at various places and reunions and these sorts of things.
I just had a huge crush on her since forever.
But she is amazing.
She is, I mean, it's ridiculous to to even like try to put words to that.
But I've always known I wanted to marry her and I did so.
That's amazing.
That's amazing.
Did you say you moved 14 times before you were 16?
Yeah.
That's a lot of moving around.
Yeah, we did a lot of moving around.
Yeah.
Why did you move around so much?
You know, it was essentially my dad working very, very hard to find whatever work he could to provide
for us.
Essentially, every move was a way to keep providing for the family.
It gave me a really interesting perspective on the United States.
I've seen a lot of different parts of the United States and the Midwest and the American
West and really fell deeply in love with this country and its people. And so that's really motivated a lot of my life.
And you guys were on food stamps.
Yes. Yeah. Yeah, we grew up quite poor and grew up in neighborhoods where our car was stolen. We'd
come home from church and there's people getting arrested on our front lawn. And surprisingly,
you'd think that that
would cause my parents to try to keep us insulated and inside.
But actually, we explored all around,
friends with all the neighbors, that sort of thing,
and watching very, very different lifestyles from ours.
I was friends with the guy who stole our car.
And I think the fact that we were friends gave him some access to be able to steal the car. And I think like the fact that we were friends gave him some access to be able to
steal the car and like, you know, we forgave him and we got the car back and whatever.
But yeah, like it was a, it was a very dynamic childhood that exposed me to probably a lot
of risk and learned how to take proper amounts of risk and how to not get myself into dangerous
situations, how to get myself myself into dangerous situations, how to
get myself out of dangerous situations, that sort of thing. So it gave me a very unique
perspective. It also taught me to work extraordinarily hard.
My dad has worked
unbelievably hard every single day of his life that I've ever known him.
And I've always just deeply admired that. What does he do? So he's done a bunch of different things, really just whatever he could find to do.
And he worked in marketing for a while,
he worked in software consulting,
and just slowly worked his way up the chain.
So now he's a successful consultant in software
and doing well for themselves up in Idaho.
But I'm counting the days until I can buy him a very, very nice estate up in North Idaho.
So yeah, it's exciting.
Good son.
Good son.
We'll see.
So you dropped out of high school at age 16.
Yes.
Why did you drop out of high school at age 16?
So there were two reasons.
I always knew that I wanted to start this company.
Well, I won't say always.
I've known since middle school that I wanted to start this company.
I've always been obsessed with nuclear.
And, you know, I was obsessed with nuclear because of my great
grandfather, who is a nuclear physicist on the Manhattan project.
And I was very close to my great grandmother who only died a few years ago.
Actually, she died when she was 100.
And I was very close to her and I kind of grew up talking to her about the Manhattan Project and the history of nuclear.
So I was always obsessed with that.
And I've known since I was about five years old that all I really want to do with my life is make thousands of machines.
But I didn't really know like which machines I should make. I do with my life is make thousands of machines.
But I didn't really know which machines I should make. I just knew I needed to make
thousands of machines. It's just something that I've always wanted to do. But I thought
nuclear was sort of covered. I thought people generally had it in hand because I would read
these books about the history of nuclear and there's hundreds of different designs of reactors
and they're all super sophisticated, super genius designs and there's a million smart people in the field. And so I kind
of had the mentality that like they've got it under control, they don't need me, right? And so
that was my mentality was more of a hobby. But when I got to middle school, I started looking for
who is the Elon of nuclear, right? What's the Tesla or the SpaceX or the Ford or the Apple of nuclear? Like who, who has really taken this thing and created a trillion dollar company around it?
And the answer to that question is no one.
In middle school.
Yeah.
You're doing this research in middle school.
That's right.
I mean, I was, I was obsessed with Elon way back in the early days before Tesla, actually
back when they were launching Falcon 1 for the first time.
And I was sort of like, who's doing this, you know, in, in nuclear. And again, the answer was like, no, no when they were launching Falcon 1 for the first time.
And I was sort of like, who's doing this in nuclear? And again, the answer was like nobody.
And that really surprised me.
And I started reading, I'd always read about the physics
and I read every physics textbook I could find,
that sort of thing.
But when I got to this, I was like, well,
what does the business landscape look like?
Who's figured out how to make money from this?
And I found that nobody had,
like nobody had been able to build a huge business
that was extremely successful
and was scaling all over the world to build nuclear power.
That kind of stopped me in my tracks.
And I was like, wait, why has nobody cracked this?
And that launched sort of a multi-year research project
of like, how would you fix nuclear?
There must be something wrong here.
What's going on?
And, you know, by the time I was like 15 or so, I had basically figured it out in my head.
Like, I think I know what's wrong.
And so I wanted to start a company.
But again, group report, I didn't know that venture capital was a thing.
I didn't know that venture capital was a thing. I didn't know that existed.
And all I knew was that in order to start SpaceX,
Elon had sold Zip2, which is a company that he started,
and then PayPal, and that had given him enough money
to then go start SpaceX,
and he put a lot of money into that.
And so I figured that's probably what I needed to do.
And I knew there were already many, many smart people
in the field with PhDs in nuclear engineering
and nuclear physics who are smarter than I was ever going to be.
When I was thinking about how do I go about fixing nuclear energy and starting this company,
I realized that the biggest problem for me to tackle was not going to school, going to
college.
It was gaining wealth and gaining business experience. My naiv, you know, my naivete said,
well, then college is a waste of time.
And so I dropped out of school to start a business.
I was 16.
By that point, I had already taught myself
software engineering.
So by the time I was a 16 year old,
I was already making six figures in my parents basement,
writing software, you know, just read books. I found a book on C- my parents' basement, writing software.
Just read books. I found a book on C-sharp on my dad's shelf.
My dad's not a software engineer,
but he's just a curious guy.
So he had a book on C-sharp.
I picked it up.
I read it, wrote some programs.
And yeah, by the time I was 16,
I was making really good money doing that
for various people just on a contract basis.
So I thought, well, I've got a little bit of money here.
I can go start a business.
Um, I can sell that one.
I could start another one.
I could sell that one and then I'll get to starting Valor.
So that was my plan.
Um, what did your parents think about you dropping out of school at age 16?
Um, they were surprised.
I don't know that maybe they weren't that surprised.
They were like a little bit hesitant, but I don't know, maybe they weren't that surprised. They were a little bit hesitant, but I don't know, I think my dad's philosophy of life
for us was like, by the time you're 14, you're generally an adult and you know what you're
going to do and you can do what you want.
So he explicitly told me that.
Were you in some type of an accelerated educational program or just?
We were in a bunch of different schools all over the place.
My mom is a very, very intelligent woman.
She just finished her college degree a couple of years ago, actually.
She dropped out of college to have my sister and then me, but she's just naturally very, very smart.
And I talked with her about math and physics and that kind of stuff all the time.
And she did a great job of, of teaching us.
Um, and so, you know, and I, I had the opportunity to go to a, a great, uh, public
school in Colorado as well, that had some really fantastic teachers in it.
Uh, one particular, uh, physics teacher, Mr.
Halevin, if you're watching this, uh, was very inspiring to very inspiring to me and taught kind of a core of guys in that class,
physics, and really kind of took us under his wing to do that.
And so, yeah, you know, I felt like
I had understood the fundamentals well enough.
And again, there's already so many smart people in nuclear
who are like the smartest people in the world
and are always going to be smarter than I am.
And the problem is like,
not the technical side, not the physics, but nobody's figured out how to,
from a business scaling manufacturing perspective,
take this as a company and scale it all over the world.
And that's what I was obsessed with
and that's what I was focused on.
So it just made the most sense for me to drop out,
start my own business, get experience,
try to get some money.
And that's essentially what I did.
It didn't work out nearly as well as it did in PayPal,
but it worked out like well enough and I learned a ton.
And then I also learned that like venture capital exists
and then you can go raise money.
So that was an eye-opener.
I figured that out when I was like early 20s
and I realized, okay, maybe I don't actually need
to spend the next decade of my life
trying to start companies that I don't care about in order to get to the one that
I do care about.
And so I was able to start this.
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You see time and time again, people defending themselves,
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financial and tax professional. So how so did you use VC? Yes, so we're a VC backed
company, an amazing set of investors who I'm extremely grateful to
in both San Francisco and Los Angeles. I started the company, I filed it on July 4th, 2023. So we're coming up on the two year anniversary of filing the company.
But for the first six to eight months, I was really just raising money. It was essentially me,
my friend Elijah, and I had written this like 200 page memo on how to fix nuclear energy.
And it was essentially just me running around like handing that to people and like saying
like, Hey, can I have a couple million dollars to go do this?
And I finally found somebody who said yes.
So no shit.
What sold them?
What do you think sold them?
I mean, I think so I'll tell you who it was.
Steve Marcus is the founder of Riot Ventures, which is a great deep tech fund in LA.
And the thing that's super unique about Steve is, first of all, he's MIT trained.
Second of all, he started a bunch of his own companies before he got into venture, which
means that he just thinks for himself.
And the problem in venture today that nobody's really figured out how to solve is that it's
full of people who don't think for themselves.
And I would say that if you read my memo, you would see that there are the
ingredients in there that are going to be a trillion dollar company.
And if you have the confidence in your own intellect to be able to read that
and break down the assumptions, you can find that, right?
But if you're looking at it from more of a signaling perspective or, you know,
what are other people going to think about this?
You might not get there.
So it really took a very unique person who understands the world on his own terms to
write that check.
How many people did you have to pitch to before you?
I pitched 80 different VC firms.
80 different VC firms.
Yeah.
And I got 80 nos.
Yeah.
What do you mean that a lot of the VCs don't people involved don't think for themselves
They just straightforwardly don't VCs do not do not trust their own
Intellect to understand a concept in front of them what they're trying to understand generally this again
So it's a split right?
There's a couple VCs who are incredibly smart people who think for themselves, who trust their own minds to understand concepts.
But that's like a very small portion.
Pretty much all of the rest of them are trying to figure out like, is this company going
to get funded in the next round or two?
Which really has very little to do with the concept in front of them and more to do with
like what network is this person from?
Who does he know?
And I was from Zero Network and knew nobody.
I was like literally living in a town of 20,000 people in North Idaho,
um, with the, with like a crazy idea. So, uh, that like, that was just not something that they were, they were used to.
They were not looking at me and the idea they were looking at, like, where am I
from, what networks am I going to get future capital down the road?
Um, which I think is a really bad way to underwrite companies.
Like that's not how you should invest.
You should invest based on who the person is, what their concept is, how,
how well do they understand the world and do you agree with how they see the world?
But that's a rare person.
Interesting.
Interesting.
And so when, when you're in middle school thinking about starting
in a nuclear reactor company,
what were some of the deficiencies?
Why nuclear?
Were you into power?
Did you research how weak the power grid is?
So obviously, my family history on the Manhattan Project gave me a predisposition to be interested
in nuclear. But I would like to
think that I was extremely objective and wanted to find genuinely the cheapest way to make power.
That's really what I cared about. And I was willing for that to not be nuclear. In fact,
for a while I would say it was actually a little bit anti-nuclear, maybe a little bit as a personal
anger that this thing that I had been obsessed with for a long time wasn't happening. It was but anti-nuclear, maybe a little bit as like a personal anger
that this thing that I had been obsessed with
for a long time wasn't happening, right?
It was really confusing to me.
So nuclear today makes about 6% of world energy, right?
So the electricity, about 6% of the global electric grid
comes from nuclear reactors, which is really small,
way too small.
And the fact that that's true
and that you can look at all the most recent nuclear projects
and they're over schedule and over budget
and like not worth it, made me think for a while like,
okay, maybe I missed something,
maybe nuclear is not as good as I thought.
And so when I was 14 or 15,
I kind of went through this like journey
in this process of like, all right,
well, I'm gonna back all the way up and try to think about like, what is the best form of
energy?
What is going to be cheapest over the next hundred years?
Because I recognize that energy is going to matter over the next hundred years way more
than it's ever mattered in the past.
As an economy, we are trending toward advanced manufacturing and AI.
And what does that mean?
Well, essentially it means that what we think of as like producing things today
is a mix of inputs from labor to raw materials, to a little bit of energy, but
advanced manufacturing and robotics and AI basically turn everything into an
energy function.
So like you've got a, you know, we've got a cool water bottle right here
with the Sean Rein show branding on it.
Today, like if you're going to purchase this bottle,
there's a mix of like costs that go into this.
And some of them are labor costs and some of them are raw material costs.
And there's a bit of energy cost in that.
But if the factory is completely automated, then there's no labor cost.
And if the materials are also automated, right?
Like there's autonomous mining equipment
that gets the aluminum, right?
And then it's run through an electrolyzer to get,
you know, to electrolyze the box site.
And then it's run through an automated factory.
Well, what's the cost?
It's just energy, right?
So like eventually this thing is just gonna cost energy.
And so I realized like that's where we're heading.
And what that means is we need a ton of power and like civilizationally, like
nationally, we need a ton of power if we're going to compete.
So I knew that this was incredibly important.
Um, and, uh, and so I backed up and I said like, what is the best form of energy?
And I looked into, uh, every form of energy generation.
I looked into solar, I looked into wind, I looked into geothermal, oil and gas,
fusion, basically every, everything that we have on the table today.
And I came back to nuclear.
I realized nuclear really is the best, but we've been doing it wrong.
We've been building it all wrong.
And so that's kind of what I focused on.
We're going to go into a little bit of conspiracy land.
Okay.
That sounds great.
If you, let's talk about Nikola Tesla.
Okay.
You looked into that stuff.
I mean, somebody that's.
Are you talking about Zero, is this Zero Point Energy or?
Yeah.
Yeah.
Yeah.
Yeah.
Okay.
So I don't know a ton about Zero Point.
I've looked into it a tiny bit.
I, Nikola Tesla is a very inspiring figure to me for sure.
And I think we need a lot more people like him.
I will say my default frame is energy is abundant
in the universe.
So would I be surprised to find a cheat code
where you can find just enormous amounts of energy?
I would not be surprised by that at all.
Like I think that there's this mindset
that there are no cheat codes and that you have to like,
you know, you have to suffer for any outcome.
And there's a human sense in which that's true.
But in the physical world, I think it's a lot more abundant
than people assume.
I think nuclear is a cheat code.
Compared to energy generation in the past,
nuclear fission is a cheat code.
It's free energy.
It's just abundant free energy everywhere.
So the concept of something like Zero Point existing
wouldn't surprise me.
That said, I'm really focused on technology, not science.
Right, so we're a technology company, not a science company,
which means we're using engineering
to take known scientific principles
to make energy cheap throughout the world.
So my basic thought on that is like,
if somebody cracks
zero point, they'll beat me. But I don't think they will. I don't think they will.
You don't think they will? Yeah. Yeah. Yeah. That's just, it's just a fascinating subject
to me. Yeah. Yeah. Go over and do it a couple of times, but I never really got anywhere.
Yeah. So what are some of the, what are some of the challenges? I mean, we were talking at breakfast and I mean,
to build a nuclear facility,
I think you said it takes 20 years worth of paperwork.
Yeah, 20 years of all kinds of nonsense,
sometimes worse, right?
And that's mostly characteristic of nuclear
in a very specific scenario,
which is in the West in the last 30 years.
If you look outside of those two parameters, you'll find much, much
better performance, right?
So if you look outside the West China, you'll find much wrap, you know, much
more rapid building of nuclear power.
And if you look outside the last 30 years, you'll also find much more
rapid building of nuclear power.
But we're in this weird Eddie of last 30 years in the West,
we forgot how to build nuclear reactors properly.
And this was really what I figured out when I was 15.
I kind of figured out a couple things that I identified
as here's how you would go about fixing nuclear.
So the first one is,
I realized that the reactors just need to be smaller.
This sounds you know super
Basic, but but I think it's true. We're really good at building small things and we're really bad at building big things
So especially now right in the 50s and 60s
We were building huge civil infrastructure projects and we were super good at that and we had massive
Pools of labor that were really good at that right right? People who could lay rebar really well,
people who could do mass concrete laying,
who could build very large structures,
who were super good at large-scale welding,
and those skills and pieces of labor
sort of atrophied over the last 50 years,
which is unfortunate, but it's true.
And then the other thing is tooling. So we don't have the capacity for like extremely large scale forging anymore.
We're just not good at forging extremely large objects as well as we were.
So I looked at both of these things and saw that like, okay,
if you're going to reboot nuclear today,
you need to be inside the labor and tool chain that exists,
which means smaller objects.
We're really good at making objects about the size of a bus. to be inside the labor and tool chain that exists, which means smaller objects.
We're really good at making objects
about the size of a bus.
If you try to make an object larger than approximately
a bus in at least the Western supply chains,
you're gonna have a really hard time.
The tools just don't exist.
You're gonna have to be making custom tools.
You're gonna have to be using pools of labor,
which cost a lot of money
and there just aren't enough people trained.
So that was kind of my first conclusion is like,
it's probably gonna be a bus sized object.
And then if that's not making enough power,
then you just make more of them, right?
And that's very in line with manufacturing.
You wanna make the same thing over and over.
That's how you get deep efficiencies.
The second thing that I realized was that
the reason that hasn't happened yet is essentially
because the regulatory environment has become too restricted for one specific thing, and
that is testing.
So, the regulatory framework for testing became very onerous and pretty much impossible.
And so, people have had these ideas before.
People have thought about, like, well, maybe we should try to make reactors smaller. And there's been a lot of people who've tried that, but they kind of ran into the
brick wall of nuclear nuclear regulation.
And we're not able to get those prototypes off the ground.
And so, um, taking these two conclusions, um, my formulation for like, how do you
fix nuclear energy when I was 15 is we're going to make smaller reactors.
We're going to find a regulatory framework where we can rapidly move through
prototypes, which means we're going to find a very unconventional regulatory
path to do testing.
And then finally, once you have a nuclear site, we're going to build tons
of reactors on that site, right?
So you don't just build one, you don't just build four, you build a hundred or
200 or 1000,
all in the same place.
And the reason for this is that the most complicated part of nuclear is not actually the physical
reactor itself.
Reactors are medium complicated.
Like I would argue that a nuclear reactor is less complicated than a diesel engine,
for example.
It's significantly less complicated than a diesel engine.
Oh, shit.
It is, yeah.
They're mechanically simple machines.
The thing that's complicated about them is the permission to do them on a certain patch
of land.
Right?
So you pick a piece of land and the process to go from, it's an empty patch to the reactor
sitting there through permitting, through environmental work, through community buy-in,
through construction, security.
There's a lot of factors that go into getting nuclear
to happen somewhere.
Once you've done that, you've done the hard part.
And so the natural conclusion is you should double down
on that, right?
So you already have a nuclear site,
why not keep building reactors there
and keep doing that like way more than anyone
thinks is possible.
So this is really sort of the core DNA of Valor
and these are conclusions that I had when I was 15 and I've really been working on that now for the last 10 years Wow, we haven't built any
Meaningful nuclear facilities in about 40 years, correct? So we built two we built two
So two units turned on in Georgia
Vogel one, sorry Vogel three and Vogel four
So these were sort of additions to an existing plant
and those turned on in I think 2019 and 2020, I believe, is when those turned on.
So we have two. Now, that project was a disaster.
It was eight years over timeline and about $15 billion over budget.
So it's a travesty, really.
Power should be cheap, right?
The whole point of nuclear is that it's cheap.
That should be the point of nuclear, at least.
So I would say that that was a failure.
Hinkley Point C in the UK is another example of this.
Many years over budget, billions and billions of dollars over budget.
And so our only recent examples of building nuclear
in the West are essentially failures.
Wow.
What is, like I had mentioned,
we had talked a lot about bureaucrats and bureaucracy
and how it gets in the way.
And so what are some of the reasons that nuclear
has been pushed to the side and stalled?
And why have we not been innovating in the nuclear sector?
So it's all downstream of public perception, right?
We can talk about the regulators locking things down too much, which is absolutely true, especially
when it comes to testing.
But the reason they did that is essentially responding to public sentiment.
So what drove public sentiment away from nuclear?
Well, I think it was a combination of like, people naturally fear new things,
the atomic bombs and the nuclear bombs sort of being associated with nuclear.
And then I think some really specific intentional propaganda.
I believe that rivals of the United States have continuously funded environmental
groups to spread a narrative about nuclear and even to sue nuclear projects.
Who stemmed? Where did that stem from?
So I think there's a couple of sources. Russia is known to be a source of this.
No shit.
This is public record now that Russia, most recently, like in the last five years in Europe,
funded far left environmental groups to advocate for shutting down nuclear power in Europe
so that Europe would become more dependent on Russian natural gas.
Wow.
This is just public record.
I did not know that.
Yeah.
So, I mean, they fell head over heels for the PSYOP,
that nuclear was unsafe, that it was not clean.
Right?
This is the biggest scandal of environmental policy,
environmental advocacy in the last 50 years,
is that the environmental groups, in theory,
have good goals.
You want the earth to be clean.
You don't want to pollute it.
You want our kids to be able to live in beautiful places with nature.
On the surface, it's very easy to get people to get on board with that mission.
But nuclear energy is so obviously the best possible solution to clean power.
It's just pure physics.
It emits no carbon, it emits no particulates.
The only thing that you have to deal with
after running a nuclear reactor
is incredibly, incredibly small safe pellets
that you encase into concrete casks
and they have no effect on the environment at all.
So there's basically no impact to the environment and they provide clean power.
You know, so like, this is a very, very obvious thing that
environmental groups should love, but they were co-opted.
They were co-opted by external money that wanted the nuclear industry to fail
and wants the United States to fail and wanted Europe to fail or become more
dependent on other sources from our rivals.
And so I think that you know, and a lot of people just bought into that a lot of people,
you know, there's always good people and any bad thing and the good people just
believed the narrative. They believed that nuclear was unsafe and they believed that
you know, nuclear waste was a huge problem.
Neither of those things are true.
Nuclear waste is not a huge problem.
And nuclear reactors are the safest form of power
generation on Earth, full stop.
And so are you saying that Russia funded US NGOs to
basically shit on the nuclear?
Yes. OK. Yes. Just like it on the nuclear. Yes.
Okay. Yes.
The, uh, like they did in Europe.
Yes.
The, the Sierra club, if, uh, if any members of Congress want to start some
investigations, uh, I would start by looking at the Sierra club and, uh, the,
the advocacy that they did against nuclear, um, especially around environmental law.
They figured out how to essentially shut down nuclear by suing over safety regulations and environmental policy
To prevent nuclear projects from happening and obviously, you know mass
Sort of social advocacy against nuclear and I believe that they had significant foreign funding to push those narratives Wow
What are some of the government players that get in the way? I have DOD, DOE, NRC.
Yeah, so this is an interesting one, right?
Like let's talk about why regulations exist and what the good case for regulation is,
right?
So nuclear has the potential to cause harm to humans and the environment if it's done
wrong and we need to do a lot of it, right?
So the natural conclusion to that is you need a regulator.
A regulator is gonna protect the public
and protect the environment
from things going wrong in nuclear energy.
This is the same for any mass industry, right?
If you have a chemical plant, you have regulators
which make sure that those chemicals
aren't gonna leak into the river, right?
If you have even a coal station, right?
Or a natural gas station, you're gonna have regulators which make sure
that it doesn't blow up and it doesn't kill people.
So this is a good thing that we have as part of society.
Now, one thing I think people miss about regulations
is that regulators in particular
really only know how to regulate things that exist.
They don't know how to regulate things
that don't exist yet.
And what that means is that you have to always have
an open space for innovation, right?
We're an innovative country.
We're a country that has, that sources a lot of our power,
power in the political sense, from technology.
We are a technological society that wields power
throughout the world through our technological supremacy.
And if you want that to maintain, if you want that to stay true, you need innovation. You need
to continue allowing entrepreneurs to push what technology is forward every year. And the way that
you do that is you allow them to innovate and you allow them to test. So the mistake that regulators
sometimes make in various industries is that they try to apply
the same regulatory framework to existing technology.
They try to take that and then apply it to innovation.
That doesn't work, right?
Cause innovation is new, right?
Innovation is about technology that doesn't exist yet.
And you can only regulate things that exist.
Like you're putting down guardrails
around a thing that exists.
So some industries have figured out how to do this really well.
So I would say aviation is a good example.
Aviation has a robust test framework where if you have an idea for an airplane,
you can go take it out into the desert.
You can build your plane and you can fly it and you can even crash it.
Right.
You try not to crash it, but like there's a regulatory framework that allows you to test.
What that means is that in aerospace, you get to very, very quickly move through these
different prototypes and aviation is now this incredibly safe thing.
It's safer than driving.
Flying on a commercial jet is safer than driving your car.
The only reason that's possible is because the regulators have created this space where innovators can just like test stuff
So that's what's been missing in nuclear primarily
You can talk about all sorts of other problems with the NRC
We're talking about a Lara talking about linear no threshold some of the bad policies that have you know
Taking the sort of existing industry and corrupted it and made it expensive
But I would say even more fundamental than that is that you have to test.
If we're gonna be dominant in nuclear,
you have to allow innovators, entrepreneurs, technologists
to create a small reactor, turn it on, and test it out.
If you can't do that, you don't have an industry,
or at least you won't have an industry in a decade or two.
Who is the NRC?
So the Nuclear Regulatory Commission
is a commission created by Congress
in the Atomic Energy Act of 1946.
It's sort of gone through a couple iterations
in various acts of Congress since then,
but it has five commissioners
and it's responsible for regulating nuclear.
And I would say it's not done a good job of that.
And the evidence for the fact
that it has not done a good job of that. And the evidence for the fact that it has not done a good job of that is since 1979,
the NRC has approved four construction permits. Four. One, two, since when?
Since 1979.
Geez.
In the meantime, China has built dozens of reactors and is currently building 30.
So there are 30 nuclear reactors under construction in China today.
Wow.
And, uh, that's a brand new thing for China, right?
China has like just gotten into this.
Uh, but since 1979, the NRC has granted four construction permits.
That's a, that's a dead regulator, right?
That, that is a regulator which needs rapid overhaul, fundamental overhaul.
Um, and the, the Trump administration is working on that.
So I'm very grateful about that.
What is, I mean, it sounds like the Trump administration's been very easy to work
with for innovators like yourself.
And so what are they doing that's different?
Absolutely.
Listen, I think this Trump administration is going to usher in the nuclear golden
age.
I am unbelievably excited about it. This administration is going to usher in the nuclear golden age. I am unbelievably excited about it.
This administration is very unique.
I have never seen such a density of talented, motivated people working
in government before.
If you talk to the people who are in the white house, who are in the agencies
today, they are not the people that you would normally see, you know, working
in government, um, in many, many cases, they are people who are taking sometimes 10x pay cuts.
They're making 10% of what they were making in the private sector, but they're doing it
out of a spirit of national service.
They believe that this is an existential threat to the country to fix these issues, to be
able to make power again.
You have people making genuine life sacrifices to work in government and to fix these issues, to be able to make power again. And so you have people making genuine life sacrifices
to work in government and to fix it.
And I mean, you have to give President Trump credit
for that in bringing this unbelievably talented,
motivated group of people together to do that.
This is all, it's all action, right?
If you go into any of the agencies today,
you would have seen in the last 20 years, really, you would have
seen a lot of policies and a lot of papers and a lot of thoughts and very little action. And today,
it's all action everywhere. Wow. Are you in contact with Chris Wright, Secretary of Energy?
So Chris is probably the best example of this. And it's easy for me to say because I'm a nuclear
and the DOE is leading the charge on this. But from Chris, all the way down through his staff, you have the most motivated people
I've ever seen picking up the baton from the president.
There's these executive orders that went out three weeks ago.
They basically gave the mandate to the Department of Energy that we need to turn on nuclear
reactors immediately.
In fact, they set a date. So by July 4th, 2026, the president has ordered
that the DOE allow three advanced reactors
to turn on on American soil outside the national lab system.
So this is unbelievably exciting.
It's what the nuclear industry
has been waiting for for decades.
This is what we need.
This is that test framework that we have to have
in order to beat China. And again, like the reason this is what we need. This is that test framework that we have to have in order to beat China.
And again, like the reason this is happening
is that the administration recognizes
that we must beat China on AI, on manufacturing.
We have to reshore the ability to build things
in the real world.
And so I would say everybody in the administration
is absolutely focused and dialed on
how do we allow American entrepreneurs to move forward
and to do what we do best, which is innovate and build the best technology in the world.
Perfect.
Well, Isaiah, let's take a quick break.
When we come back, I want to talk about how bad our power grid is.
Sounds good.
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All right, Isaiah, we're back from the break.
I wanted to talk about some of the vulnerabilities in our power grid system and I think you would
be the perfect guy to talk to about that.
So I've dove into this quite a few times with different, with different guests.
The first one was actually a guy that made a documentary about how vulnerable our grid is.
And I mean, he's talking about how much of our grid is manufactured in China from solar panels to
transformers to vulnerabilities and power stations and how they're not guarded.
And I mean, I mean, you, everybody sees me drive by on the side of the road and it's got a chain-link fence
and maybe if you're lucky, some barbed wire up top.
And he talks about how somebody could get in there and just shoot those up
and basically disable them, how it would take years to get a new transformer
because they're so large and most of them come from China.
They would have to take overpasses out to get them in place.
Talks about Trojan horses and malware and the grid system.
Absolutely.
Anyways, without covering all of it, I want to talk to you about what kind of vulnerabilities
do we face?
Yeah.
Well, first of all, I would just point out that the grid is old.
I think fundamentally the grid, it's an old piece of infrastructure.
And it's part of this whole decay problem that we've had in the United States where we've stopped building physical world technology.
And we've also stopped building physical world technology that has anything to
do with like civil infrastructure.
And part of this is a legal problem. We've also stopped building physical world technology that has anything to do with like civil infrastructure.
And part of this is a legal problem.
It's because our environmental laws became extremely overbearing and made it hard to do anything.
And it's also because we stopped manufacturing here, right?
So we should make transformers in the United States.
We should make a lot of transformers here.
There are a few companies working on this, right?
Maddox Industrial Transformers, a great American company that's working on making domestic transformers.
Super, super awesome.
I hope that they can scale fast enough
to what we need to do over the next few years.
But the other thing I'd point out is,
I think technology over time becomes more decentralized.
This is a common thing that happens as technologies mature
is that you figure out how to do them in different ways.
One of the big issues with our grid is how centralized it is, which creates vulnerabilities
across a large spectrum.
Will you get a little more, what do you mean by a centralized grid?
Yeah, so the grid is so interconnected with itself and so interdependent on itself that
if you hit one piece of grid in one state, you might be taking out a piece of infrastructure
in other states.
A grid is a very balanced, tricky thing. You're trying to keep perfect synchronism between many,
many, many moving parts. It's physical machinery, it's the load side, it's transformers. All of
these are highly sensitive pieces of equipment, which are syncing up around this 60 Hertz, right?
So 60 times per second,
switching the polarity of an electrical field,
and many very complicated pieces of equipment
plugging into that.
And the larger you make that system,
I would argue the more fragile you make the system, right?
Because a failure in one area
can cause a failure in the entire thing.
And there's lots of protections and safeguards
that we try to add to make sure that doesn't happen.
But there's a fundamental principle here,
which is that a centralized system is a vulnerable system.
If you can take out one piece of it,
the rest of it goes down.
We saw this in Spain a couple of months ago.
And so I think the other than the very obvious things to do,
which is secure infrastructure, apply cybersecurity, companies like Galvanic working on that.
And trying to manufacture things here and making sure that we actually are building new grid infrastructure.
I also think that we move toward a concept called micro grids. So micro grids are exactly what they sound like. They are smaller grids. And rather than trying to have a perfectly in sync, extremely large system,
you have more smaller systems so that no matter what, if you take down, you know,
this piece of infrastructure, you've taken down like one town, right?
Or maybe two, but you're not, you haven't taken down an entire state.
So this kind of goes back to what we were talking about at the beginning, where
one of your reactors could power a small town.
So each town would have their own reactor and that would be a decentralized grid.
That would be decentralized.
I think that it's probably not one town to one reactor.
It's probably a cluster of towns to a cluster of reactors, but I think that we're certainly
moving closer to that and less how it is today, which is like groups of states
that are sharing grids with each other
and then sharing vulnerabilities with each other,
especially as I think loads become a lot more spiky.
So what is a spiky load?
Well, it means like you have a data center
which is consuming a ton of power.
Previously data centers were like 50 megawatts max.
That was like the biggest data center.
And then it became a couple hundred megawatts. And now we're looking at gigawatt scale data centers were like 50 megawatts max. That was the biggest data center. And then it became a couple hundred megawatts.
And now we're looking at gigawatt scale data centers.
We're going to start to see microgrids evolve
from huge power demand sources, which is good,
because trying to add a massive load to the grid
is going to exhaust not just the resources,
but trying to follow the demand for that load
becomes increasingly tenuous
and the consequences are just larger. So, I think, again, if we want to fix this problem,
there's really simple things to do. Fix the environmental policy to make it possible to build grid infrastructure.
So we're talking about NEPA, we're talking about state-level reforms. Build things in the United States again,
transformers and other power electronics, and build smaller grids. And I would also argue it should be
somewhat generation led. You find a good place to generate energy. It's a good place to put
10 nuclear reactors, 100 nuclear reactors down, build a microgrid around that for data
centers for manufacturing, and then start to share that energy, start to expand that
grid out a little bit. But I think that the old style of massively centralized systems
is probably going away a little bit, and that's a good thing.
Another reason that I think that we went this centralized
direction was that our power generating units used
to be much larger.
So you'd have gigawatt scale power generation,
which needed a very large base to hook into.
You have a gigawatt scale reactor.
Reactors traditionally were not load following.
Now they are, but they traditionally were not load following.
You have to plug into a really broad base of demand.
Now that reactors are load following
and that the reactors that we make are going to be smaller, you actually can, you know, just put a couple of these reactors onto a single grid or even 10 and you're only at 250 megawatts.
So smaller, more decentralized, much, much less vulnerable to centralized attack.
So if we're talking about decentralized power grids, does that mean that we would have to reinvent the entire grid to make it decentralized?
Because if everything's centralized right now. We're going to have to, we're going to have to reinvent the entire grid to make it decentralized
because if everything's centralized right now.
We're gonna have to reinvent it.
Like let's not kid ourselves.
Over the next 30 years,
we're gonna have to reinvent the entire grid
no matter what, right?
Even if we decided that we're gonna continue
with centralization,
in order to triple our grid capacity,
you're gonna build a lot of infrastructure, right?
So I think this is not an option to not reinvent the grid.
The grid will be reinvented and it's either going to be reinvented with more
bigger centralized infrastructure, or it's going to be reinvented around
dynamic, smaller decentralized infrastructure.
And I think that second one is the right way to go.
It definitely sounds like it's the right way to go.
I mean, now redoing our entire grid.
I mean, that is a, that is a huge project, but it seems like
nobody has, it almost seems like everybody's scared to touch it.
The only place that I've seen upgrade their infrastructure, and this is just from a visibility
standpoint, is I have family in Florida, I'm from Florida, hurricanes
wiped the grid out. You go back down there and you see what they build and it's not wooden
telephone poles that look like they're going to fall over. They're these huge metal, maybe
steel. I don't know what the hell they are, but they're definitely metal power lines.
Is that what it would look like or what is, what's going to carry the load
on a decentralized grid?
Yeah, absolutely. New power line infrastructure. Again, I think one of the reasons that people
are afraid of this issue is, is that we haven't properly brought private industry and capitalism
into that solution set, right? America is incredibly good at using its technologists
to solve thorny problems, and we use the profit
incentive to do that.
Right?
People like me, people like my employees who see an opportunity to solve an enormous problem
and make an enormous amount of money in the process.
Right?
This is how we as Americans figure out how to solve the hardest problems on earth.
And the way that you can muck up that process is by introducing laws and legislations that
make it impossible to fix the problem with the profit incentive through private companies.
And the way that we've done that is through, again, environmental policy, through some
of the centralized federal regulatory programs around the grid.
When you try to manage all of this at the top, you become very bad at governing, right?
The higher you try to govern a thing,
the worse you become at governing it.
Now there's a too small version as well,
so there's some middle point here.
But the middle point is much further toward decentralization
than it is toward centralization today.
There's actually a concept here
that I'm sure you're aware of called anti-fragility.
I'm not aware of that.
So this is a Nassim Taleb concept and there are systems which
benefit from chaos and there are systems which are punished by
chaos or degrade from, from chaos.
So this is generally called like fragile, robust, and anti-fragile.
A fragile system, a glass is a good example of this.
A glass is a fragile thing.
If you knock it with a hammer, it could shatter.
A steel cup would be an example of a robust thing.
If you knock it with a hammer, it's probably fine.
But then there's this third category of thing
which is called anti-fragile.
And what that means is like,
the more you knock it with the hammer, the better it gets.
And I would argue that what you just mentioned in Florida
is a good example of this,
where the fact that they have hurricanes
which knock out the grid infrastructure
actually means that they have a better grid, right?
Because the chaos of that situation
has allowed them to figure out how to evolve
and to get better.
And if you look at human systems, the best human systems are anti-fragile, and capitalism is an anti-fragile system. Private companies using the profit incentive
to fix problems on a smaller scale, on a decentralized scale, is extremely anti-fragile.
If you add chaos into that, people actually learn and get better and grow rather than becoming more fragile.
So when you're thinking about governance, I think this is just a general property of regulation.
It's like you need to figure out how to make that system anti-fragile, which means allowing for variance.
You have to allow for different people and different companies to do things different ways.
And that's exactly what microgrids are, right?
Utah has a different idea of what a microgrid is than
Ercat in Texas, for example.
And those different ideas will look slightly different
in the world, and they'll have different outcomes.
And then we can compare and contrast.
And you could say, oh, they did that really well here.
Let's copy that over there.
Oh, Florida figured out how to make this resilient.
Let's copy it in California, right?
Whereas if you try to keep everything
highly centralized at the top,
you don't go through that learning process
and you become increasingly fragile over time.
So I think that today that's exactly where our grid is.
It's very fragile.
And it's fragile because it's centralized
because it does not admit a variance
because it's done the exact same way everywhere
because it's federally regulated by environmental policy.
FERC would be an example.
Other regulations that touch that for power electronics.
And so if we want to fix this problem,
you need to use capitalism to fix it.
That's what we're really good at as Americans.
And to do that, you have to decentralize.
You have to let different companies
try different strategies and fix the problem.
Why do you think, this may be a little off topic
from what we're talking about, but I always wonder,
you know, why are we not putting the power lines underground?
That seems to be where they would be the least fragile.
So, and the technical reason for this is resistance.
So you're gonna lose power.
Power does not travel through the cable.
It travels through the electrical field around the cable.
And so if a power line is underground,
you have resistance with the ground,
the electrical field, the electromagnetic field
is actually traveling through the dirt
and you're picking up all sorts of resistance along that.
So bearing cables, now maybe we're making off energy
that we don't care about that.
We just decide to bury it.
But another way to think about this is like is keep it above ground because it's cheaper that
way, and because you lose less energy, and then have it more decentralized, which means
one cable set going down doesn't destroy the whole grid.
That's an alternative way to do it, and then you don't really have to worry about the fact
that they're above ground, or that one transformer got blown up or these sorts of things.
If it's broken up into smaller risk areas
and it's diversified,
then you just don't have to worry
about these problems that much
and the system solves itself.
So if the electrical current is actually
on the exterior of the power line,
is what it sounds like.
Yes.
Question for you, could you put the lines in a pipe?
Yep. Like a pipe? Yep.
Like a, like a covert or something.
Yeah.
Another way you can do this is with, um, insulation, that sort of thing.
Again, anything underground is, is more expensive, right?
You're, you're digging, you know, you've got groundwork, you're thinking
about ground stability, these sorts of things, and these are problems we figured out.
So the short answer to your question is like, yes, you certainly could bury the
lines and that would solve some of the vulnerability problem.
And my argument to that would be like, let's try that.
Let's try that in a microgrid and let's try another grid over here that has above ground
infrastructure and we're going to learn a lot of lessons and maybe we'll find out that
the buried infrastructure had a different vulnerability than the above ground did.
But if this one goes down, this one didn't, and we learn and evolve through time.
And that's really how technology works.
All of technology is something that learns
and evolves through time.
It's not static.
I think this is one thing that people miss
about technology is that it's constantly changing.
And the danger of regulation,
and I think one of the tasks that the next 10 to 15 years
of American law and policy is going to have to
figure out is to figure out how to allow technology to evolve in that way and how to try to decentralize
a lot of the policy that we've put in place.
Because frankly, we're getting outbuilt.
We're getting outbuilt all over the world.
China is building not just nuclear reactors better than us, but now they're building cars
better than us. We didn they're building cars better than us, right?
We didn't expect that to happen.
And in all these cases, I would say that we're not properly allowing entrepreneurs
to build the right technology and we're centralizing it too much.
Well, you know, I guess China too, I just had this gentleman, Steve Quast on,
I don't know if you've heard, he's got a company called SpaceBuilt,
and he was talking about how China's mining helium-3 off the backside of the moon
Okay. Yep, and do you know anything about helium-3? I do. Yeah, you know, I think
This is one of these things China
China is not just out building us with technology. They're doing some really interesting things in science as well. I
Don't particularly think that helium-3 is the right
Scientific solution night. I think that our energy technology is better than helium-3. But it's a good example of like,
China is outbuilding us. They're outbuilding us in the physical world. And we were sleepy.
Frankly, the American technology industry has become sleepy in pretty much everything
except software.
In software, we still have an edge and we've led in AI in many cases,
and we've certainly led in software products.
But now we're starting to bump up against physical limits in software
because we need data centers and we don't have them.
We need powerful data centers and we don't have it.
So even where we have been excelling, which is software,
we're starting to hit the limits of the fact that we just haven't been building enough.
So in every area, we have to fix this with the way that Americans do things,
which is private companies motivated by profit, solving a huge problem.
And the way that we do that is through decentralization, through deregulation,
through allowing Americans to go build.
When you're talking about a decentralized grid and testing and all these things, I mean,
knowing not much, I would think that you can't take a small town of 15,000 people and say, hey, you guys are going to be our test case. Maybe you could.
Yeah.
But if so, is that what you would do to test the microgrid or would you do something like,
hey, we're going to power this data center, we're going to power this shopping complex
or something like that?
No, that's exactly right.
Yeah, no, I think it's going to be piloted in data centers.
It already is being piloted in some data centers.
And that's where I think the natural evolution here is that you're gonna have these,
what I call industrial power campuses.
At Valor, we call these gigasites.
A gigasite is essentially a place
where we build many nuclear reactors.
We power data centers, we power aluminum electrolysis,
we power advanced manufacturing, we create chemical fuels.
So there's a great amount of power.
And that power begins to be sold outside of that,
very small industrial grid, well, large power, small footprint industrial grid.
And we begin to serve communities outside of that.
So I think it's going to be a natural evolution.
Um, and there needs to be regulatory change for that to happen.
Um, only a few States have like sort of figured this out and gotten ahead of the ball
and, and drafted and passed legislation to make this legal.
Uh, Utah is, is one of them.
That's where our first nuclear project is in the United States. But there are other states. What are you powering there?
So we, I went on Bloomberg a couple of weeks
ago with the governor of Utah.
And we announced together that we have the San
Rafael Energy Research Center in Emory County,
Utah, where we're going to be turning
on our first test reactor.
So super exciting.
The goal is July 4th next year. Incredibly, incredibly important. Energy Research Center in Emory County, Utah, where we're going to be turning on our first test reactor. So super exciting.
The goal is July 4th next year.
Incredibly, incredibly important, important moment for the United States if we can hit
that date.
Extremely excited about it.
We'll build more reactors there as well.
And I do think we'll power data centers there.
And beyond the data centers, again, there will be electrolysis.
There will be manufacturing and we'll see where it goes after that.
Our thought here is that we need to begin building power
for the most critical things.
And if we allow ourselves to deregulate and decentralize,
the problem will sort of fix itself, right?
Because people need power
and there's these new generation sources coming online
in their own grids.
And you can start just to hook it up, right?
One small project at a time, which again, you can use the profit motive for that.
You'll have companies who are in the business of, you know, hooking up this
line to that line and separating this grid from that grid and, you know,
beginning to do that in a, in a natural fashion, uh, which is what we're really good at.
What are some of the red pills that nobody, the nuclear red pills
that nobody's talking about?
Yeah, nuclear is really counterintuitive.
People do not understand the magnitude of nuclear.
So before I talk about nuclear, let's talk about coal for a second.
So coal is really cool.
I like coal a lot.
If you're holding a chunk of coal in your hand, you're holding a pretty extraordinary
thing, right?
You're holding a chunk of coal in your hand, you're holding a pretty extraordinary thing, right?
You're holding a chunk of energy and that's super exciting.
So, you know, if you're digging and you find a chunk of coal, what have you found?
Well, holding it in your hand, the chunk of coal that fits about the size of your
hand has so much energy in it.
It has enough energy to propel you, your body, about five and a half miles into the sky.
Right?
If you expended all that energy on pushing you up off the surface of the planet, you would go about five and a half miles into the sky.
Um, if you put that into a car, right.
It's a big, heavy thing.
You know, it can take all your family and your groceries and everything.
You can go about 10 miles down the road with, you know, that, that chunk of coal.
So it's an extraordinary, extraordinary thing.
And it served us very well as humanity to be able to do that.
Now one very, very counterintuitive fact about nuclear is that nuclear fuel is spread all
throughout the earth.
There's a couple of caches and deposits of uranium and thorium that are more concentrated.
But nuclear in general is just like spread throughout the earth.
So about 10 parts per million of every just rock outside has,
you know, 10 parts per million is nuclear material.
There's trace nuclear material in basically every rock that you pick up outside.
Here's a crazy fact for you.
So we talked about this chunk of coal that fits in your hand and how much energy it has in it.
If you go outside the studio right now and you find a rock that's the same size,
and you ask how much energy is in that nuclear energy,
the answer is about a hundred times more energy than the chunk of coal.
Are you serious?
Every single rock that you pick up outside of the studio is as if you're holding a 100
X chunk of coal in terms of energy.
If you take those trace amounts of uranium and thorium and you were to fully fission
those in a fast reactor, you would get 100 times more energy, which is to take our original
example enough to propel you about 30 kilometers, your body
off of the Earth.
About a third of the way to space.
Every single rock that you find out in the garden on the side of the road.
Nuclear is the future.
You can look at that and say, okay, when we discovered nuclear energy, we essentially
discovered that the entire planet is as valuable
as a coal mine, right, which is very valuable and very energetic.
So I think people underestimate radically how much nuclear fuel there is.
It's under our feet at all times.
We could be using it.
We should be using it.
You had mentioned being able to convert, I don't know the terminology, you mentioned
being able to convert nuclear into burning clean gas or something like that.
Can you elaborate on that?
Yes.
So this is really, really exciting.
We talked a little bit before, I think before we started started cameras here about what is the future of energy look like?
Do we use all nuclear?
Do we continue using oil and gas?
A very contrarian thing that I believe is that I think that humanity continues to use
hydrocarbons, right?
So we're talking about diesel, jet fuel, gasoline for a long time.
And in fact, I think that hydrocarbons are sort of the perfect fuel.
It's hard to imagine a better fuel than a hydrocarbon.
It's very dense.
It could be a liquid.
It's non-toxic.
It has elements you already find in the atmosphere.
It's one half of an oxidation reaction, which means the oxygen is already there.
So you only have to carry half of it, right?
Normally with chemical energy, you need to carry two buckets around, right?
And then you mix the buckets and you get heat.
Well, hydrocarbons, you only carry one bucket
because the other half of the buckets in the air,
it's oxygen.
So it's sort of the perfect fuel that you could imagine.
But where does it come from, right?
So right now it comes from underground, which is fine.
It's served humanity very, very well.
We've propelled ourselves to the civilization that we are today, essentially through drilling oil and burning it. And that's
awesome. But I think we can do even better. The way that we do even better is that we are eventually
going to get hydrocarbons from the air. What do I mean by that? Well, the air already has all the
ingredients for hydrocarbon. It has carbon and hydrogen, right?
So the carbon is in co2 which is everywhere in the atmosphere
The hydrogen is from water which is also everywhere in the atmosphere and all you need to do is energize co2 and water
So it's sort of think about this like reversing combustion, right?
So when you have combustion you start with a hydrocarbon and you mix it with oxygen and you get energy out of
that and you get CO2 in water. So that's combustion in a normal
engine. We kind of do the opposite. We start with those
combustion ingredients, the CO2 in the water, we put energy back
into them and we get a hydrocarbon. So I believe that
that process will be driven by nuclear. And what that means is
we're essentially using hydrocarbons
as a distribution mechanism for very cheap nuclear power.
So if you have a bunch of nuclear reactors all on a campus,
again, we call this a gigasite,
you're producing huge amounts of power,
and we can certainly push electrons in a wire
and produce electricity,
but we can distribute all of that valuable energy
in another
way, which is to build hydrocarbons and then ship the hydrocarbon. Right? So this is like us producing
energy, forming it into a hydrocarbon and then shipping that energy in the form of a hydrocarbon.
And I do believe that as nuclear becomes cheaper and cheaper, that the price of that hydrocarbon
is going to become significantly cheaper than oil
It'll become cheaper than than drilling oil and refining it and distributing it interesting. You know, I am
Kind of surprised to hear you say that we still have a place for fossil fuels. Absolutely, you know, I mean we see you know
Obviously Tesla. Yeah, they're doing the dates. I saw I think it was last week They started the robo taxis in Austin, you know, a lot of the cars are going to batteries
Talk to Dino Mavroukas the CEO of Saronic and he's talking about how they're powering their small boats and batteries some of the bigger ones are doing diesel, but yeah, I mean why do you why wouldn't you want to put a
Small modular nuclear reactor
in something like a naval vessel or a car
and get rid of all this shit?
Yeah, so I think the short answer is like,
EVs are gonna continue to be a massive thing.
I have a Tesla Model 3, I love it.
It's amazing, I never have to fill it up.
I also have a gas car as well,
and that's useful for other use cases.
I think the answer is we're going to do a lot more of both.
We'll have a lot more battery powered things and we'll have a lot more
hydrocarbons. And the reason is there's something very irreplaceable
about a hydrocarbon. And those things are energy density, right?
So energy density, meaning how much energy do you get per weight and per volume?
So if you have a container,
you have a box that you're putting either a battery in
or you're putting a fuel tank in,
hydrocarbons are about 40 times better than batteries.
In the same amount of space, you can carry 40 times,
sorry, the same amount of weight, 40 times the energy.
That's pretty irreplaceable for things like aircraft, for example, right?
An F-35 Lightning is never going to be powered
by lithium ion, it's just not, right?
You have to get the power density of a hydrocarbon
to run that thing.
There's a class of ships, right,
which will always need something with the energy density
of a hydrocarbon, you just can't fit all those batteries and they're going to be too heavy to run,
you know, a long range ship, short range ships for sure, smaller ships for sure.
And then absolutely there will be some nuclear vessels as well, but there's just this really
broad set of use cases where you need energy density and hydrocarbons just have such incredible
irreplaceable energy density. The other thing is there.
And nuclear wouldn't fill that.
So for cars, for example, I don't think so.
I don't think that we'll have nuclear cars.
Or let me say it another way.
I think we will have nuclear cars,
but it will be nuclear generated diesel
that then goes into a car.
Gotcha.
Or nuclear generated electricity that powers a car.
Nuclear reactors don't like being small. There's sort
of a minimum size that you want to build a nuclear reactor and trying to get it smaller
than that is a very, very difficult engineering challenge. It's a safety challenge. It's a
weight challenge. It's an exotic materials challenge. So there's sort of a good form
factor for a nuclear reactor. And then, you know, what it does is make really cheap energy
and you can transfer that energy to other forms.
You can turn it into electrons, power battery,
you can turn it into jet fuel, power jet.
But hydrocarbon is such a beautiful thing.
It's a liquid, right?
I think we take hydrocarbons for granted.
The fact that hydrocarbons are a liquid
is this insane unlock.
Like think about the fact that you can like pour energy into a container.
That's irreplaceable, right?
If you need to go and take fuel to somebody in a remote location, you're not taking a
battery, right?
You're taking a canister of fuel unless you're prepared to carry 40 more containers for the
same amount of energy. And so yeah, there's all of these
places where hydrocarbons are
civilizational level technology, which we should not replace quickly.
One more example of this is actually distribution. This is very counterintuitive.
I like to point out to people we talked about the energy grid, the electrical grid,
and we think of the electrical grid as the way
that we move energy around the world. But the electrical grid is actually a very, very small
fraction of how we move energy around the world. It's very tiny. How we actually move energy around
the world is by shipping hydrocarbons. The numbers here is about 8%. 8% of energy movement is electric.
8% of energy movement is electric, 92% of energy movement is hydrocarbon.
So just an example, we talked about different scales of power, gigawatts and megawatts.
The largest electrical site on planet Earth is the Three Gorges Dam in China.
So it's the largest concrete structure ever created by humans.
Massive massive hydroelectric dam in China.
It has a nominal nameplate generation of about 22 gigawatts and practicality makes about
17 gigawatts.
Huge, huge energy facility.
And it distributes these through massive electrical cables that snake all throughout China.
We have a pipeline coming down from Canada called the Keystone Pipeline.
The Keystone Pipeline is a pipe about this wide. It's standard steel, right, about that thick.
And you can calculate how much energy does that thing push. And this is going to be a chemical
energy figure, not electrical, but it's basically the same thing, it's just energy.
It's not electrical, but it's basically the same thing. It's just energy.
The Keystone pipeline moves about 50 gigawatts
of continuous power.
So about two, three gorgeous dams.
We can call it six gorgeous dam if you want.
Two to three times the three gorgeous dam worth of power
in a pipeline that's this big.
Wow.
So hydrocarbons are civilizational level
technology.
They are required to move energy between nations
to power high energy density formats to get to Mars. If we want to go to Mars, we're doing
that with hydrocarbons. Starship is powered by methane, which is a hydrocarbon. So there's
all of these use cases, which I think are very underappreciated and we'll continue to
use hydrocarbons for a very long time.
You know, earlier also we had talked about how Russia is influencing NGOs and lobbying firms
and stuff about to create a narrative against nuclear.
And so I'm curious, I mean, when it comes to energy,
it's obviously a very profitable business.
And so when you are a threat to oil and gas. Yeah.
Um, green energy still, I mean, do you, do you feel like you have narratives against you that are put on through them?
I mean, I read something.
I don't know, maybe about six months ago that said that you remember the big
power outage in Texas when they had that winter storm was that last year or two years ago?
Yeah, two years ago, yeah, something like that.
We had all heard, oh, it's because the solar panels were freezing and the wind turbines
were freezing.
What I actually read was that the pipelines from gas were freezing and the gas industry
was really on top of it and had created this narrative and pushed
it out that it was, oh, the wind turbines had frozen, the solar panels had snow and
shit on them and they couldn't produce.
And so, if it was true, which I don't know if it is, then that's maybe you know, was
that true?
Yeah, no, that's absolutely right.
The freeze in Texas was very related to gas.
Yeah, no, that's, that's absolutely right. The, the freeze in Texas was very related to, to gas.
Yeah, absolutely.
There's temperature profiles where, where gas doesn't work as well, especially
if you don't build it for that.
And this was a very uncharacteristic event for Texas and it hadn't
really been, been built for that.
Yeah.
So it is true.
So, I mean, so right there, I mean, oil and gas was on, on their game
and pushed a narrative, which was a false narrative
that was, you know, the blamed wind and solar.
So is that happening to you?
Is oil and gas, is wind and solar. Are they pushing narratives out about nuclear
to hinder your business?
I think that industries will always
sort of jockey against each other,
and PR firms will always try to find ways to shift blame.
I do think that in the 80s, there's
good evidence that the oil and gas industry funded
some of the narratives against nuclear.
I put this in sort of like, I don't call it fair game.
It's not something that I would do,
but it's something you should expect in business.
In business, you should expect counter narratives.
But, you know, what's more interesting to me today is like,
how much of the physics is inevitable?
Because at the end of the day,
you can only lie to people for so long.
And I do think that people have been lied to about nuclear.
And one of the reasons that I'm so excited to be building now is that we're
building in the information age, right?
So the fact that you discovered that narrative, right?
About what was happening in aircott is a product of the fact that we live
in an age of the internet, right?
So these narratives only last for so long, uh, in an age when information
travels at the speed of light. And we all have X and we all have podcasts that we listen to and these sorts of things.
So I think that nuclear has been under this narrative burden coming from rivals and maybe oil and gas a little bit, maybe renewables and you know, just everybody's starting to recognize that nuclear is the cheapest and the safest
and the cleanest form of power on Earth, that it is going to power our future.
And also that the demand for energy is so enormous that I think it's kind of pushed
away a lot of the competition feeling between the generation sources.
Like listen, guys, we need to triple the grid.
There's no
Boxing each other out if you can get Nat gas on faster than I can get nuclear on power to you, right?
We're all going as fast as we can and we're still not gonna be able to catch up to the actual demand for generation
So I think there's a little bit more camaraderie than there was maybe 20 30 years ago, you know
also when it comes to the
The safety of nuclear I mean we had talked, I talked
about this with Scott Nolan as well, but you know he was talking about you take the seeds or whatever
you call them and you put them in the concrete, you just mentioned that, you know something that
didn't come to my mind when I was interviewing Scott is you know what are some things that
could happen? What if, I mean China's obviously our biggest adversary at this point?
and so what would happen, you know when you
Put those seeds or those pellets pellets and in into concrete and bury them when they're
When they're obsolete. Yep. I mean what would happen if
China were to bomb
Yeah, whatever facility holds holds those inert pellets.
Yeah.
So this is one of the things that they look at when they design these casks.
They look at various kinetic events, they look at impact events and analyze that exact
question, what would happen?
And the short answer is that the amount of energy that you would need to actually cause
a dispersal event,
it's way more worth it to bomb something else. The outcome of that is, yes, you could
put such a strong kinetic there that theoretically, if you kept bombing it, you could get through the concrete and you can get through the containment and then you can get through the trisodotri-particle
ceramic itself. Now you've got some fizzle product dispersal.
And you can map how that dispersal works.
And in theory, you could imagine some people getting cancer
and probably not that many, right?
Unless it's like stored in the center of New York City,
which is unlikely.
But once you do all that math, you realize,
well, with that level of ordinance,
there are a
lot more interesting targets to hit, right?
Um, the outcome that you're going to get from that is like not at all worth the
amount of ordinance that you need to do something like that.
Um, not trying to give people ideas, but like, that's just not a, a very
highly leveraged use of, uh, a terrorist event, right?
Um, the other thing is, of course,
we have lots of safeguards and protections
around the nuclear fuel, right?
Not just fences, but like armed security
and these sorts of things.
So yeah, I mean, I think like the nuclear waste concern
has been highly overplayed.
People have played it up to a degree
that's just not commensurate with the facts
because it's kind of the easiest target for nuclear, right? It sounds scary, like, oh,
there's nuclear waste and people don't know what that means. But the fact is, nuclear waste is
the safest form of waste of any power generation.
No kidding.
It's the safest. So if you look at, you know, I always hesitate to compare nuclear to oil and gas because
I have a great deal of affection for oil and gas.
I think that oil and gas has powered the modern world.
We would not be anywhere close to where we are as a civilization without oil and gas.
But it has downsides, right?
It may be farther if we had gone with nuclear earlier.
Absolutely.
Absolutely would be farther if we had gone with nuclear earlier.
But still, I have an enormous amount of gratitude for the
oil and gas industry for powering humanity to this point.
But we did that with trade-offs and those trade-offs are known.
Right?
You are at a much, much higher risk of cancer living near a coal
plant than living near a nuclear plant.
That's just fact.
That's just scientific empirical fact.
The reason for that is that coal ash and the types of stuff that you're digging up from
underground when you burn it gets into the surrounding environment and can cause cancer.
As a civilization, we have to make these trade-offs.
We have to say, we need power.
Power is existential.
If people don't have power, they die during the winter or they die in heat stroke during
the summer. And so you don't get to choose between zero deaths and zero deaths.
You're choosing between civilizational existence or die out and some level of death that is
going to happen.
Right?
And in coal, there's a number, in gas, there's a number, in solar, there's a number.
And actually, nuclear has the lowest number.
Nuclear has the fewest deaths per generated power of any form of energy generation.
So it is simply the safest.
What would happen if China were to hit your reactors?
So our reactors in particular, we get a lot of benefit out of two things.
One is the fact that our reactors are very low power density.
So what does that mean?
It just means per unit volume of our reactors,
there's not as much fissile material inside of them.
So we have a lot of benefit out of the box
and just that are, as a target,
it's a low density target, right?
You don't get a lot of bang for your buck.
The other thing is that Triso itself
is an extremely, extremely powerful ceramic,
right? So you are, it's interesting, the strength of a sphere scales inversely with its size.
So what that means is the smaller the sphere, the stronger it is proportionally.
And so you take that to the limit, and this is a technology that American scientists invented.
The reason they did this is that you can, you can wrap these very, very small
beads of uranium about the, uh, you know, the tip of a ballpoint pen in these
extremely strong ceramics and proportionally that ceramic coating around
the uranium pellet, uh, is actually stronger than a containment dome.
Right?
So if you look at a traditional nuclear reactor today, you have these big
concrete containment
domes and those domes are built to answer the question you asked, like what if you dropped
a bomb, what if you crashed a plane, these sorts of things.
And so they have these highly engineered strong concrete domes to try to prevent that.
But we actually build the dome into the fuel with TRISO.
So the fuel itself contains all of these tiny domes around them.
And those domes are actually are stronger than a massive engineered concrete dome.
So in some sort of kinetic event, you are much less likely to have those ceramic
spheres bursting essentially, then, you know, then what would happen if you
crashed one into an existing nuclear dome.
Interesting, interesting.
Thanks for explaining that.
Let's talk about some of the, some of the ethos of Valor.
Yes.
Valor is a very unique place.
It's very unique in nuclear.
We really fundamentally believe that in order to build nuclear reactors, you need to build nuclear reactors.
This sounds facetious, but it's not.
It sounds exactly like what it sounds like.
There's a philosophy that came from the 50s and 60s,
which says that you kind of do a long design period for nuclear reactors,
and then you do a long licensing period for nuclear reactors.
And at the end of that, you have a design and a license,
and then you hope that somebody comes and buys your design
that's stamped by a regulator, and you do a construction project and build it.
The problem with that is that like
we've stopped building reactors.
And so that system only works
if it's something you're doing constantly, right?
It's something that works in steady state.
But if you ever stop,
you've lost all of the skills to do that, right?
You've, you know, the people who were there,
you know, have retired or died. The people who could
have done those exact pieces of construction have retired or died. We don't have the tooling
anymore. You actually have to build nuclear to build nuclear. For us, it means starting
very small. We start with a very small, very simple, very safe reactor that we can build
very quickly, and we get experience in the hardware.
And we started that really on day zero,
hiring the first engineer in the company,
and we designed what's called a thermal prototype.
So that's what's sitting in Los Angeles today.
It's a thermal prototype is essentially,
you build a nuclear reactor,
but you don't put uranium in it yet.
You put electrical resistors,
and you can get those electrical resistors up to the same temperature
as a nuclear reaction.
So you get to essentially simulate what if this were
a real nuclear reactor with electrical heat.
And so that's essentially what we've done.
We did it in one year.
It's the fastest that a thermal prototype
has ever been developed.
It's also the most sophisticated thermal prototype
ever developed.
It genuinely is a nuclear reactor.
We built a nuclear reactor in one year without putting uranium in it.
And now the next step for the company is to go do it again, but actually put
uranium in it and actually turn it on.
And this is going to give us a lot of experience, right?
We're actually going to have split the atom, which is something
that not many people can claim.
And then we'll do it again and we'll do it again.
And that's how this is going to progress.
It's going to progress through real hardware,
through real prototypes, through actually splitting atoms.
And you can always get more sophisticated later,
but you start very simple, very, very safe,
and you get real experience as fast as you can.
How far out are you from splitting an atom?
So the goal today, you know,
I set by the president is July 4th, 2026.
So we're going to try to hit that date.
Um, I'm confident that we're going to hit it.
How do you split an atom?
So nuclear fission, uh, is not as complicated as it sounds.
Like I said, it's significantly simpler than a diesel engine.
Um, so here's how it works.
You have nuclear material, which in most cases is uranium 235.
So the 235 isotope ofope of uranium has fewer neutrons
than the normal naturally occurring isotope, which means it's unstable.
And that instability means that when you hit it with a neutron, it will split into fragments.
And that explosion into fragments at the atomic level produces an enormous amount of heat.
The energy of those fragments is heat, essentially.
Now, how do you do this?
How do you make sure that those neutrons hit those atoms?
Essentially, what you do is that you assemble uranium
into a certain pattern with what's called a moderator.
So a moderator scatters neutrons geometrically. So there's
sort of a configuration of moderator, which in our case is graphite. We use pure graphite.
It's essentially crystalline carbon and uranium. And if you configure it the right way, you
can model it where if a uranium atom splits, it releases a neutron and that neutron will
hit the graphite and it'll scatter
around and then it'll eventually hit another uranium atom.
And that uranium atom will split, release two more neutrons, and those will scatter around.
And then hopefully those two will hit uranium.
Those will call two more splits.
And so you have four neutrons and then eight and then 16, 32, 64, 128, 256, 512.
That's an exponential growth function.
So you have an exponential growth of neutrons
that are especially more and more neutrons
scattering around inside of this graphite core
and the graphite is responsible
for making sure they scatter back in to hit more uranium.
And eventually you have heat production.
That neutron production rate goes up and up and the heat goes up and up. And so now you have heat production. That neutron production rate goes up and up, and the heat goes up
and up, and so now you have a hot core. You can use that heat. What you do then is you
take a fluid and you pass it through the core, and the fluid gets hot. You have hot fluid
coming out of the reactor, and you can use that hot fluid for useful things. You can
spin a turbine with it. You can create hydrogen with it. You can heat a home heat a home if you really wanted to, right? There's lots of ways you can use that
heat. And so you cool that as you run it through something useful, and then it comes back into
the reactor and gets heated up again. So you have essentially a heat loop, and you're heating
it up with uranium that's undergoing fission in a nuclear core. Actually, mechanically
pretty simple, right? Kind of a stable core of fluid looping through it.
That's basically it.
Another rabbit hole here.
Are you familiar with CERN?
Yes.
What's going on over there?
Lots of conspiracies about this.
Sounds similar to me.
Yes, CERN is doing particle acceleration.
And, you know, I don't know too much about what they're doing.
I've heard some of the fun conspiracies. I
Was am I'm probably less susceptible myself to like scientific conspiracy. I
think that
people feel
conspiratorial about scientific topics because it's generally driven by the government and
The government has done some sketchy things, right?
The government's done some weird stuff and so they see you know, the the lab coats and the government has done some sketchy things, right? The government's done some weird stuff.
And so they see, you know, the lab coats
and the government money hidden underground.
And they're like, there's some weird stuff going on there.
I tend to think that there is weird stuff
going on in the government that does need to be rooted out,
but it's probably less on that sort of like edge science.
And it's probably more medical things and, you know,
things having to do with like censorship
and social media and those types of topics
rather than the scientific.
To be honest, like American scientists are very smart,
but they're really slow at this point.
I would be more impressed with,
well, CERN is not American,
but Western scientists, let's say that. I would be more impressed with, well, CERN's not American, but Western scientists, let's say that.
I would be more impressed if Western scientists
at this point were being maniacally competent.
That would be a deviation
from what I think is actually happening,
which is we're all kind of wasting time.
I think most of the scientific apparatus today
is wasting time.
We're kind of pushing paper around
instead of doing
really, really unique edge research. And that's because of how it's funded and how the universities
are today, which is, you know, they don't like taking risks, they don't like pushing boundaries.
You have to say the right things. So I think it's pretty unlikely that we even have the competence
to be doing anything to Nefarious. Yeah. That's good to hear. Isaiah, let's take another quick break. When we come
back I want to talk about the size of your reactors, who's interested in them,
and a lot of that kind of stuff. Awesome.
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All right, Isaiah, we're back from the break.
We're getting ready to talk about the size of these things that you're building.
I want to know how fast you can build them.
And so I've read, we talked about earlier, a hundred thousand
pound reactor.
What is a hundred thousand pound or how big is it?
So it's a actually pretty easy to visualize.
It's the size of a shipping container stood on its head.
So 20 foot ISO cube.
And, uh, it's basically the, the whole reactor vessel kind of
sitting inside that frame.
You can kind of think about this like a big water bottle,
right, so shipping container sized water bottle
and it's full of nuclear grade graphite
and we'll put uranium in that eventually.
So just a big old heavy water bottle.
One of the really unique things about our design
is how simple it is.
We try to keep this as simple as we possibly can.
Complexity means cost, it means time,
it also means less safety, right?
So you wanna keep things simple, very understandable,
easy to manufacture, easy to build.
We'll make that a little bit bigger over time.
So it'll go at least 1.7 times larger.
And that'll be a little bit more powerful.
But to start off with, we have essentially one big vessel
inside of a container
and we have other containers on the side as well, which do other things. So that's like
the main nuclear vessel. And then we have a power conversion skid next to it that actually
spins a turbine and has the helium flowing through it and that sort of thing. So we keep
it really simple. We try to keep it manufacturable. That's really the thing that we focused on
safety and manufacturability. We want to build these really, really fast.
How big are you going to go?
So this is a good question.
And I think I am purposefully trying to make sure I don't think I know the answer to it.
Yeah.
I have ideas, but part of the whole point of technology is like, you have to discover
things by doing them and by getting closer to them.
So I have lots of thoughts on like how like how big you should build the eventual reactors that
power the entire world.
I think that we know that the next reactor we build, the 1.7x scale up of the current
one that we have in Los Angeles, is the right size to hit an amazing price to be able to
make the cheapest power in the world and to build them really fast.
So like that's good enough, right?
And we'll start to scale with that.
Over time, I think it's likely
that we'll get bigger and better,
but every time you get bigger,
you have to, the safety gets harder, right?
So like you have to pay a lot more attention
to what happens in an emergency scenario,
how to get the energy out of the core.
And it gets harder to build.
You have to have more advanced tools.
It's harder to transport, right?
The logistics get more difficult.
And so we think this size is like a really great way
to hit the ground running, put gigawatts of power
down onto the grid, power data centers,
beat China on AI in the very immediate term.
And then over time, this is similar to SpaceX, right?
Where they start with the Falcon 1, which is a small rocket and then Falcon 9 and now Starship is this huge rocket. You wanna get bigger over time, this is similar to SpaceX, right? Where they start with the Falcon 1, which is a small rocket,
and then Falcon 9, and now Starship is this huge rocket.
You want to get bigger over time because you're
going to figure out those tool sets which
allow you to do that a little bit at a time.
So it sounds like, and we've kind of discussed,
I mean, you want a model that's easy to manufacture
and get out the door.
Just print these things out, stamp them out.
How fast can you make it?
So it's a good question. And the reason that we built this thermal prototype was to prove that we can make it really fast.
So this is truly extraordinary what the team has done in the last year.
We have one of the most talented nuclear teams on planet Earth.
They have deep, deep experience in nuclear. You know, the founding engineering team at Valor
had over 90 years of experience
with this exact type of nuclear reactor,
which is a high temperature gas reactor.
So unbelievably experienced team,
and they have moved very fast.
So we spent about six months in engineering of the reactor.
So this was all on paper, right?
Design, CAD, analysis, this sort of thing.
And then we spent four months fabricating it, assembling it, and commissioning it.
So four months, yes. Four months.
Yes. How fast do you think that will get?
I would like to see us pumping out this model of reactor essentially every two and a half weeks.
And the reason for that two and a half week constraint is it's about as fast as you can
get some of the welding procedures.
So you're welding a nuclear pressure vessel,
the heads, the body, the flanges,
all these different things.
And there's some serialized timelines
in the welding procedures and heat treating
and these sorts of things that are hard to compress
below two and a half weeks.
And so what we do instead is we parallelize at that point.
So we make multiple vessels at once. So on a particular site, we could be going even faster than, you know,
three and a half weeks, but sort of the time from like one unit start to one unit end,
we'll probably stabilize around three weeks. Do you think you'll stay in El Segundo?
So South Bay LA, El Segundo, or as we affectionately call it, the gundo,
So, South Bay LA, El Segundo, or as we affectionately call it, the Gundo, is an amazing place to have a highly innovative company, to have access to the best engineers in the world.
Truly the best engineers, the most talented fabricators, machinists live in South Bay
Los Angeles, and that's why we're there.
I think over time, the business will operate in many different places around the world.
We'll have nuclear reactors operating in many countries, in many states, thousands of reactors
all around the world.
So I'm not sure exactly where the center of gravity will go, but as long as there are
very smart people in South Bay LA that are working for us and that we need access to,
it makes sense for us to be there.
How many...
Is there kind of a limit of,
I mean we had talked about making a chain
of these nuclear reactors and putting them all together
to create more power for a bigger grid size
or whatever you want to call it.
If you thought about what would be the most amount
of these that you would connect together
for a single decentralized grid?
I would put in the thousands.
I would say we could have thousands of reactors chained together on a single site.
If you look at that total power rating, you're looking at like 50 to 100 gigawatts, which
would be by far the largest electrical generation station on earth.
But it would actually be similar to some of the larger oil
refineries that we have today.
So I think that's sort of the limit,
because if you build much larger power stations than that,
you're vulnerable to attack and that sort of thing.
You don't want to have all that technology centralized.
So it's more of like a, how big is that station compared
to all of your other stations and compared
to all the other generation again,
you don't want too much centralization
because that makes you vulnerable.
So I think that we will get into thousands
that puts us into the same classes
like the largest oil refineries in the world
in terms of continuous energy output.
But if we're also, if we have 15 different sites
that are in the thousands, then maybe you know, maybe you go even higher.
There's really not a fundamental limit there.
It's really just how much demand for power is there.
Interesting, interesting.
And you're doing something in space as well, correct?
Not yet, not yet.
What do you want to do there?
But I believe that, so first of all, space is, space and nuclear go well together for
a couple of reasons.
One is solar panels, if you're at the level of planet Earth, work great because you have a lot of sunlight and you don't have any shadow and you can get a lot of power.
As you move away from Earth, move away from the sun, solar irradiance becomes weaker and weaker, right? So if you wanna push a, you know, a vessel out to the edges of the solar system
or out to, you know, some of the further planets,
you need nuclear.
You have to have nuclear.
The sun's not gonna power you that far.
So nuclear for in-space transit is very interesting.
We don't think about in-space transit quite as much yet.
Maybe we will someday,
but there's a lot of smart people working on that.
What I'm more interested in is making power on Mars. So, you know, we wanna go to Mars. I think a lot of smart people working on that. What I'm more interested in is making power on Mars.
So, you know, we want to go to Mars.
I think a lot of people in my generation
are very excited about Mars.
We talked a little bit about this before
with the frontier, right?
Americans are always looking for a frontier.
And I think a lot of people in my generation
see Mars as that frontier and it's very exciting.
But one of the first things that Mars needs is power.
It needs a lot of power.
And it's not just for the local generation.
It's not just to make electricity
to turn on the lights and operate the AC on a Mars base.
It's also to get fuel to come back to Earth.
So when the first starships land,
these are Methalox starships.
So that means they have liquid methane and liquid oxygen
burning in the Raptor engines.
And like we talked about before,
methane is a hydrocarbon, right?
So what we're talking about is liquid hydrocarbons
powering the rocket to get to Mars.
Now these rockets are supposed to be reusable, right?
So they're supposed to be able to land on Mars
and then come back and get more cargo.
And they're supposed to be able to go back and forth. Well, where do you get the methane from on Mars and then come back and get more cargo and they're supposed to be able to go back and forth. Well where do you get the methane from on Mars? We
don't have methane infrastructure there, we don't have fracking and natural gas
and like all the things that we have on Earth that get us methane on Earth. So
what you can do is the same thing that we'll do here on Earth which is we'll
generate hydrocarbons from nuclear. And in some ways the challenge is actually
easier on Mars.
So for instance, the atmosphere is basically CO2.
So we don't have to worry about difficult
carbon capture systems.
You're basically just pulling in the atmosphere
to get your carbon.
And then the hydrogen is gonna come from ice.
So there's lots of ice mixed in the soil on Mars.
And so we can actually process water out of the soil.
We can run that water and that CO2
through the same systems that we use on Earth
to generate hydrocarbons and we can do it on Mars.
This is super exciting and also very counterintuitive.
We talked a little bit before about how amazing
fissile material is in this rock
that has so much power in it.
An interesting thought experiment is to think about,
let's say you have a starship that takes off from Earth
and gets to Mars, and then it needs to make its own fuel
to get back.
The question is, how much uranium do you
need to take with you on that starship
to get back from the surface of Mars to Earth?
So you're taken off, you've got a bunch of fuel,
and then you have a chunk of uranium
to power our nuclear reactors to make the fuel to get you have a chunk of uranium to power our nuclear reactors
to make the fuel to get you back. How much uranium do you have to take? You know, a starship
is a huge, huge thing. It's the largest flying object. It's basically like a flying skyscraper,
right? So you would imagine you're going to need a lot of uranium. The answer is actually
a cube about this big. You need a cube of uranium about this large to generate all of
the fuel to get that starship back to the surface of Earth again.
Wow.
So it's an unbelievably energetic and powerful format for space exploration and for terraforming on Mars.
Where are you going to... When you do these fields of chained reactors, are they going to be above ground, below ground?
What's that going to look like?
They'll be above ground. They'll be very simple.
We've already got one unit sitting in LA
that we've been testing.
We've taken it up to pressure, up to heat,
and been testing all the mechanical components.
And essentially, they'll just look
like a bunch of those next to each other out in the desert.
We're starting in Utah.
We've got our first reactor turning on there
in the next year.
It's just super exciting.
Is it going to be one?
Just one.
And then we'll build another one,
and we'll build another one and we'll
just keep doing that right off to the races.
Awesome.
Awesome.
Who are some of the, who are some of your customers?
Who, who's really interested in this?
So I think data centers have like the really obvious screaming need today.
Right.
We have to beat China on AI.
Uh, the, the Trump administration has made it clear that this is a national
security priority for them, that we have to beat China on AI. The Trump administration has made it clear that this is a national security priority for them,
that we have to beat China on AI.
So powering data centers is the really urgent concern.
Beyond that, I'm really excited about advanced manufacturing
and reshoring manufacturing to the United States.
If you think about some of the reasons that we exported
manufacturing to other countries, one of the big reasons
was labor cost.
So it's cheaper to get foreign labor to operate these factories
I think that was a mistake by the way
We shouldn't have done that we should have found ways to make the manufacturing process cheaper and to do more with less
But this is a decision we made
When we bring it back, it's gonna be more automated. It's gonna be more advanced and it's gonna use more power, right?
When you replace sort of hand labor with machines
You're essentially replacing it with energy and we need a lot of energy to do that and it's going to use more power. When you replace sort of hand labor with machines,
you're essentially replacing it with energy.
And we need a lot of energy to do that.
And so I'm really excited about how we start
to expand these power campuses to make more power
and have a factory next door and power the factory
to have metals electrolysis next door.
So to make magnesium and aluminum through electrolysis.
So I think these campuses
sort of expand into industrials. We can absolutely make power for the grid. We can make power for
communities around us. And then the really, really big goal where Valor becomes, I would argue,
the most valuable company on earth is when we begin to make liquid fuels. We begin to make
hydrogen. We bond it with CO2 and we can sell diesel, jet fuel, gasoline on the market
at a better price than the oil and gas industry can.
And that makes our demand for our product practically infinite.
The nice thing about hydrocarbons is that they're a liquid commodity.
And there's $4 trillion of demand for them all around the world,
and we can make a lot of those.
What about, I mean, I just feel like there's so many other sectors that would be interested in this other than data
centers. I mean, DOD, Defarment of Defense being one. I mean, you know, me being a SEAL,
working for the contracting for CIA, I mean, overseas power, especially in the Middle East,
in poor countries is hard to come by and more fragile than what
we have here.
Absolutely.
And so, I mean, I could see, I mean, you're talking about one of those nuclear reactors
powering a small city.
I mean, we're talking about FOBs, you know, forward operating bases overseas, very remote.
I mean, is there any DOD interest in forward deploying these things into forward operating
bases and even a major air
base like Bagram.
I mean, it just seems like, you know.
This is really one of the most critical capabilities that we could give the American military in
the next 10 years is the ability to generate their own power on bases and to generate their
own fuel.
Right?
We want to make JP-5.
Most of the military runs on JP-5 from generators to APCs to tanks to aircraft,
run on JP5. We want to be able to make those on a remote site. You remove a lot of the complex
logistics of trying to source that fuel from many different places. You remove a lot of the
casualties as well. Many of the casualties that come in four deployed locations come from trying
to move fuel around and people driving trucks and these sorts of things. So if we can make the fuel on site, that's incredibly important.
This was one of the executive orders that came out about a month ago was for the military to set up
their own capability to deploy these reactors like mine, like others on military basis. So we're
extremely excited about that. I do think that, again, this is one of the most critical capabilities that we could give
the United States military is to make their own power and to make their own fuel and be
energy independent wherever they need to go in the world.
Anybody else?
Anybody else interested?
Other customers?
Yeah.
I think energy is this interesting thing where everybody needs energy, right?
So the customer base is somewhat infinite.
It's an eight trillion dollar market.
And what we focus on is where can we deliver high impact immediately,
which is AI manufacturing and defense.
And then as we begin to make more and more power,
we're really just making energy cheaper,
which is going to benefit everybody.
Right? If you want power in your house, I think in the next 10 to 15 years, the power is going
to be cheaper because Valor Atomics is making very cheap reactors and we're powering them
and those prices are going to come down.
The goal of Valor generally throughout time is to continuously push the price of energy
further and further down.
I genuinely believe there's no lower limit to that.
Energy can be as cheap as we want it to be, and you continue to march down that path every
year of figuring out how to make it cheaper and cheaper.
And that is going to be very exciting.
How much is one of these reactors?
What's the first one going to go for?
So I'll tell you what the market pricing is for reactors, and then I'll tell you that
we're going to beat that by a lot.
The market pricing is $5,000 to $7,000 a kilowatt.
So if you want a gigawatt of energy,
you're talking about $5 to $7 billion
to purchase that gigawatt.
We will significantly beat that price.
So our goal is to be cheaper than everybody else.
I think we'll be more than cheaper than everybody else,
and just to continuously do that year after year.
How long will these reactors last?
If we plan around 20 years, and I say plan around
because you design a reactor for a certain time period
and you say after that, you can decommission it
or you can reevaluate, you can inspect it and you say,
does this have another 10 years in it?
And you decide yes or no, you can maybe recommission it for another 10 years or you just re-evaluate, you can inspect it and you say, does this have another 10 years in it? And you decide yes or no, you can
maybe recommission it for another 10 years or you just decommission it at that point.
So we do our engineering around 20 years. Now a lot of the reactors that we have today
were originally designed for 20 to 30 years, in some cases 40, and they've ended up running for
60, 70, and some have been licensed to keep going even further than that. So
nuclear is a very long-term technology.
Part of this is the fact that there's not that many moving parts, actually.
They're pretty solid, they're pretty stable,
especially our architecture that we use uses helium.
Helium is inert, so we don't have a lot of chemical reactions and corrosions in the core, that sort of thing.
So, I think they'll last a long time, but we plan around 20 years.
Are you working with Scott Nolan at all?
So Scott's working on uranium enrichment, which is extremely important.
We need to be able to enrich more uranium.
We've built our reactors around low enriched uranium.
So he's working on solving the HALU problem.
So HALU is high SA, low enriched uranium.
It's essentially uranium enriched from 5% to 20% anywhere in that range.
We use below 5%.
And the reason we do that is it exists today.
Scott's solving a problem of we just don't have HALU.
Russia makes it. We're not buying it from Russia.
We have some stockpiles which we're trying to figure out how to make available for test quantities.
But if you need these sort of like advanced
types of reactors, you need HALU. We kept it simple, right? We just said, let's use
what's off the shelf. Off the shelf is low-energy uranium. It currently powers 20% of the American
energy grid and there's lots of it. So we start there. We can use HALU over time as
it becomes available, but we like to keep it simple to begin with. Do you ever see yourself kind of scaling down to maybe a mini, like a very small reactor?
You see this movement of people that want to live off grid and, you know, in being in
control of their own energy.
And so what I'm curious about is, you know, somebody that's running a farm or that wants
to be self-sufficient on energy, not connected to the grid.
I mean, is there a world where there's a scaled down version that's not a shipping container?
It's maybe the size of a, I have no idea, a shoebox that can power your individual home.
So a shoebox is about as small as you can get a critical sphere in theory,
which means any machinery you add is going to be larger than that.
So there's sort of a minimum size of a nuclear reactor, just based on pure
physics and the physics here is essentially the mean free path of a
neutron, meaning as a neutron travels, what is it going to hit and can it be
reflected back and cause more fission?
Um, and that size is, is actually like pretty large.
So our reactor that we have in LA, it's sort of one vessel in a shipping container.
That's about as small as you can make a reactor
moderated by graphite.
OK.
And graphite's really nice.
It's a cheap material.
It's abundant.
It's easy to get.
If you want to go smaller than that,
you have to start getting into different moderators.
And that can get really expensive.
So for instance, beryllium is a moderator
that people have used for outer space, where you need a really, really small reactor that fits on
a satellite. The issue with beryllium is A, it's extremely toxic. B, it's extremely expensive.
It's essentially emeralds. Beryllium is essentially putting emeralds in your nuclear reactor.
And so yeah, we we think nuclear is a technology
that works really well at the shipping container plus size.
You can scale out, again, it's like bus-sized infrastructure.
And you can do many of them, you can make tons of power,
and the power's really cheap.
When you get to small use cases,
you're probably looking at using diesel, using solar, using things that fit in a smaller container.
But yeah, nuclear reactors, they don't like being small and then you have these safety
concerns and you have radiation, that sort of thing.
It's nice to keep them in their own little park.
Oh, good.
Oh, good.
You know, back to the...
Sorry, I have a lot of questions popping in my head right now.
So back to DOD, I mean, and I know you want to talk about a shift in nuclear policy.
Yes.
But, you know, how, is there a timeline on when DoD will start to utilize these reactors?
I mean, I talked to guys like you quite a bit, uh, within the last six months,
um, just amazing innovators and, and what you guys are doing and time and time
and time and time and time again, no matter who I'm talking to, whether it's Palmer or
Dino or you or your friend Augustus.
It's always policy that gets in the fucking way of innovation.
It's killing us.
You just said China's built 30 nuclear reactors. Yeah.
And what are we doing?
What are we doing?
Yeah.
You know, we're bitching about nonsense.
Yes.
And so, I mean, is there an actual timeline on when DOD is going to implement this?
Yeah.
Or is this just in discussions?
So I would say in DOD, it's in discussions.
DOD has a project called Pele.
Project Pele is this shipping container-sized reactor.
They want it to turn a test model of this in the dome next year.
And that's a test model, and hopefully it'll evolve to something that can start deploying on bases.
I would say the problem is no longer in the policy side.
It's now on the engineering side.
But that's only because of the executive orders
that President Trump signed a month ago.
I think that genuinely was opening the gate, right?
The gates are now down, we now have the ability to build,
we can build at speed,
and it's essentially an engineering problem from here.
So I believe that the DOD will buy the units that work, right?
And so we're gonna make the units that work,
and we're gonna be able to show them working,
and they'll be able to purchase them.
But it's hard for governments to purchase things
that don't exist.
It's always like this chicken and egg problem,
where the DOD wants something to exist in theory,
but they're not really technologists.
And so there's this interplay between private corporations
that have an idea of a product and the DOD that
has capabilities that they need.
And the way that we crack that chicken and egg is that we build a reactor that we know
works and that they can purchase.
So we're going to be doing that as fast as we can.
That unit that turns on next year is that first proof point.
So I do hope that we can put assets on military bases in the next couple of years.
What would you say your biggest hang up is, specifically?
Hang up meaning blocker in our path.
Yeah.
The blocker, I mean, this is an amazing thing to say,
and I'm very grateful that this is now something I can say,
is now engineering.
The path before us is set by our ability
to build the reactor as fast as we can, to build TRISO,
to put all of these ingredients together,
to test the systems, to make sure they're safe, to manufacture them.
This was not true up until about a month ago, which is very, very exciting.
But you have one built. You have one built.
Yes.
And so what's the hang up? It doesn't sound like an engineering problem.
Yeah. So the question is what's stopping us from just going and putting
uranium in the unit that we have today. So we need fuel.
That's sort of the next engineering challenge is
that we need to put a Triso fuel into that reactor.
One of the things that Scott talked about on his
episode is that we've really under invested in
nuclear fuel.
And this is not enriched uranium that we're talking
about now.
It's wrapping that uranium into the Triso particle.
So this is something that we invented in the United States now. It's wrapping that uranium into the triso particle.
So this is something that we invented in the United States.
So you'll hear this over and over, right?
A technology we invented here, and we kind of let it sit on the shelf,
and other countries scaled it out.
So unfortunately, China has the largest triso production capability in the world today,
of course, and it's being set up domestically as well.
So that's sort of the long lead today today is getting fuel to turn that reactor on.
But I'm excited.
I think that we'll get it on in the next year.
Perfect.
Perfect.
Anything else with policy shift that you want to chat about?
Yeah, it's really interesting.
If you think about where nuclear policy was in the United States from its inception,
nuclear policy started as essentially what I would call protectionism, right?
We wanted to protect what we had.
And what we had was essentially a total monopoly on nuclear energy and nuclear technology.
We're the only ones who knew how to do it.
Germany was trying to figure it out.
Britain caught up pretty fast.
The USSR caught up pretty fast.
But in the very earliest days, this was a total American monopoly. And our first policies
around nuclear were built to protect that monopoly and to keep this as sort of like
a closely guarded government secret that doesn't get anywhere else in the world. But as things
happen in technology, other people did figure it out, right? USSR figured it out. They became
very good at building reactors, trying to figure it out right USSR figured it out. They became very good at building reactors
China figured it out. They're now getting very good at building reactors and reactors are getting built all over the world
So the new directive from the Trump administration is about dominance And I'd say this is a shift from protectionism to dominance
The new nuclear policy in the United States is that we need to be the best in the world
We need to be the gold standard of nuclear again. That means we need to build fast, we need to build safe, and we need to build
reactors that are cost competitive. They need to be cheaper than whatever China can put in the ground.
And in order to do that, you really need to have an administration that is fully aligned on making
that happen. And that's what I'm so excited about. There's really never been a better time in the last 40 years
to build in nuclear energy.
And it would not have happened
without the leadership of the president.
He really did put his foot down and say,
we are going to be energy dominant.
We are going to sign these orders,
which empower the DOE to finally start testing reactors
again, which changed the NRC to allow us
to actually go build them.
And it's also the people around them as well.
You know, I've noticed that there's just this massive shift
from analysis to action, right?
From paper to getting stuff done.
You know, I was hearing, you know, the other day that the shift
and the feeling of added, you know, the shift in attitude
is from, you know, what 50 papers did you sign this week
to what 50 things did you sign this week to what 50
things did you get done this week, right?
What happened in the physical world?
And that is very exciting to me.
Yeah, me too, me too.
We're getting into, we want to talk about the actual cost of how much cheaper is nuclear.
Yeah.
So this is something I think few people understand.
A lot of people when they hear about nuclear energy,
what they're thinking about is it's stable, it's clean,
you know, you can, it lasts for a long time.
There's these attributes of nuclear
that they're thinking about.
And very seldom are you hearing
it's just gonna be so much cheaper.
And this is really a product
of how poorly we've been building nuclear in the West for the
last 30 years is that it became very expensive.
Opponents of nuclear will say, nuclear is $150 to $200 a megawatt hour, whereas other
forms of generation are less than 100.
Nuclear looks like the expensive option.
I would appeal to the past.
I would say, what was nuclear energy before we kind
of mucked it up, right? Before we overregulated, before Three Mile Island, before we kind of
tripped over our own feet, what was nuclear doing? And what's fascinating is that if you
go and look at the original costs of nuclear from the 1970s, it was and remains the cheapest
energy that humanity has ever experienced and that's adjusting for inflation
Right. So if you take what did nuclear energy cost in the early 1970s and adjust those numbers to today?
It was around 35 to 40 dollars a megawatt hour, which is cheaper than the cheapest energy on earth today
So we've actually gotten more expensive in in every way since the early 1970s
And again, we're not talking about nominal 1970s dollars.
This is inflation adjusted, which proves to me
from a physics perspective and an engineering perspective
that nuclear can obviously be the cheapest source of energy
because we did it before.
We've already proved it.
And so we just have to get back there.
Now, what's also interesting is that even in the early 1970s,
that was only, what, 20 years is that even in the early 1970s, that was only, what, 20
years since we even invented nuclear, right?
It was 20 years since we turned on the first reactors.
And so that technology was like pretty new, and it was already the cheapest energy on
Earth.
So where would we be if we had continued to march down that line?
Where would we be if we had continued to let innovators innovate and make these things
cheaper as technology does over time?
And that's what I'm really excited about with Valor.
So the first goal is we're going to get back to energy being, nuclear energy being the cheapest and then we're going to go further.
It's going to get cheaper and cheaper and that's going to be really exciting.
I mean, I think I've read that 90% of the cost is lawyers and all this bureaucracy type shit.
Yeah, so.
True.
Absolutely.
I mean, this is one of these things where when people talk about cost, they're really
only able to look at historical examples and they look at how projects have gone and they
total up the costs and they say, well, this is how much it costs.
But as technologists, you have to take a step back and look at things more fundamentally
and you have to ask how much should things cost and why.
There's a way of looking at this that I love.
It's something I believe Elon invented.
It's called the Idiot Index.
Have you heard of this?
No.
The Idiot Index is a really fun way to look at technology.
Essentially what you do is you look at the finished cost of a good.
How much does a thing cost on the shelf?
Then you look at the cost of the materials
that it's built out of,
and you divide the finished cost number
by the material cost number, and you get a factor, right?
So for an example, an iPhone costs, let's say $1,000,
and it's probably like 200 bucks of material, right?
So divide that and you get a factor of four.
So that'd be an idiot index of four.
And that's pretty characteristic for like mature projects,
mature products is they generally have idiot indexes anywhere from like two to seven.
A car is probably one of the lower ones.
If you buy a car for 30K, the material cost in that was somewhere around like 10 to 15K. So it has an idiot index of like two.
So mature technologies end up having an idiot index from two to seven.
The reason it's called an idiot index is because if the number is really high,
you're an idiot. Right.
If the number is super, super high, it means that you're doing something wrong.
And the goal of technology is to continue pushing that number lower and lower.
Again, you know, with with space as an example, as far as I can tell,
when Elon started SpaceX, space in general had an idiot index of about 70.
So 70 is an extraordinarily high number.
What that tells you is the rocket that's standing there was 70 times more
than the materials it's made out of in terms of cost.
So you're doing something wrong there. right? It shouldn't cost that much.
Nuclear is about 140. 140? 140.
So nuclear is about two times worse than space was
before SpaceX.
And it's, you know, 10 times to 12 times more
than it should be for a mature commercial, you know,
piece of industrial equipment, right?
So that tells us that we have an enormous amount of doing things wrong
in a system that we need to solve for.
Then the question is, how do you do things right?
The only way to do things right is to start from first principles.
You have to look at the design and say, how do we make this cheap?
How do we manufacture it easily? How do we keep it safe?
The safety has to do with the cost.
If you have a very safe reactor,
you spend a lot less time and energy
on engineering safety, right?
A very simple, very safe reactor is easier to make safe
than a reactor that's like less safe by design.
And then you end up adding a bunch of safety band-aids on it.
Let's put it that way.
So just start with something that's much safer, much simpler.
And then the other way that you drive a lower ID index is by doing the same thing over and over.
Repetition is really the fundamental way that you drive an India index lower.
This is again why we make the reactors very small and why we have this model of making many of them on a site.
I call this you do well what you do often.
So whatever you do over and over again, you're gonna do better and better.
And so you wanna get into this pattern
where you're making the same reactor
with the same tools, with the same people,
and they get better at it.
And that's what's gonna allow us to pull
all of that cost out of the system
and we'll get to cheap reactors
which are more like industrial pieces of equipment, right?
Maybe an IndyX of 10, hopefully get down to seven,
maybe even five.
Let's move into China versus the US with the AI race. Before we get into that, I want to ask you about espionage. I talked to Augustus about this. I brought up that when I worked overseas, China
would set up brothels.
Wow. All over the middle East.
I could see that. Yeah.
And pretty much anywhere the U S was at and they would set them up and you'd get
the state department guys and all, all these people going in there that are,
you know, working for NGOs, USAID, state department, you know,
insert government agency that's operating at some capacity overseas and
People go in there fall in love with the you know, Chinese spy slash prostitute. Yep. Next thing, you know, they're giving up information
I told it Augustus that yeah lunch after after our interview and I asked, you know, he goes mad that sounds exactly like
Like
Silicon Valley
and El Segundo.
It sounds like San Francisco, for sure.
You see these guys, they're nerds.
They come up.
They build something.
They get rich.
And then they have a super attractive Russian wife
or Chinese girlfriend or whatever.
And that wife slash girlfriend is selling secrets back
to wherever they came from.
I mean, how are you concerned about that?
And if you are, how are you taking
that type of a threat seriously?
Yeah, so first off, I am definitely concerned about that.
I'm especially concerned about that in places
where we do have the technological edge today, right?
So I think AI is like a really obvious example
where of course China is doing that.
They would be foolish not to do that
and we would be foolish to assume that they aren't.
So that is absolutely happening.
There have been known cases of that happening.
So you have to be very careful about it.
The other thing that I'd say today though,
is that to be honest, we're so far behind in nuclear
that China doesn't care to steal anything from us.
Right?
They're so far ahead of us.
They've built advanced reactors.
We've never built an advanced reactor on American soil.
We've never split an atom in an advanced reactor on American soil.
And China has in three now, I believe.
And so this is going to be a concern.
And we're thinking about how to address this threat over the next few years as we begin
to pull ahead of China.
But to be honest, where it stands today, they're just ahead of us.
They don't care to steal.
They view what we're building as toys, essentially, right now that they're past, which is a very
sad place to be.
And that's why we have this urgency of the moment.
I would say we have a window to catch up.
And the reason we have a window to catch up is because American entrepreneurs are the
most innovative people on earth.
We genuinely are.
We're incredible at building innovative technology using first principles thinking and incredible
engineers and building something that's never existed before.
Pretty much everything that China is doing on nuclear is stuff they copied from us, but
it's stuff they copied from us back in the sixties and seventies and eighties.
And then they've sort of brought to a new point of maturity, uh, through
experience since then, and we're still back there, right?
We're still trying to just get this stuff working.
So, um, it will be a concern as we pull ahead.
Um, but today, like, you know, man, we, we got to start splitting
atoms before they even care.
How far behind do you think we are?
I think today we are probably four or five years behind
if Valor is doing it.
If other companies are doing it, we're decades behind.
I think Valor is the only company that's moving
even close to fast enough to get anywhere close to China.
And that is something I think about a lot
and we're going to go as fast as we possibly can.
And five years, do you DC, let's say the administration, let's just say, you know, after Trump's term here,
you know, goes back to the Democrats. I mean, are Democrats on board with this?
Absolutely. Yeah. They are.
You know, I think that nuclear...
This is a bipartisan issue that
everybody's taken seriously. Nuclear became bipartisan during the Biden administration.
Now, I will say, you know, I think obviously there will be another democratic presidency
at some point. And my appeal would be that you should take a look at what the president did
and put the partisanship aside and keep fueling that fire,
because it is so important.
It is such a national security issue that we have power,
that we power our civilization,
that we reassure that we win on AI.
This should not be a partisan issue.
This should be completely bipartisan.
And it was beginning to be, I think,
the Biden administration more than other
democratic administrations before him,
were pushing nuclear. They started to make a couple of movements.
The one flaw, I think, in this for Democrats is that they tend to be very protective of bureaucracies.
They tend to be protective of the sort of like class of people who are generally Democrats
who sit in government positions and have government jobs and do the paperwork.
And I think that, you know, obviously Republicans are a little different from that.
They don't have those same classes of people.
They don't have the same loyalties toward bureaucracies and bureaucratic systems.
And so the Trump administration has been able to very, very quickly change the tone overnight,
which is amazing.
And so my appeal to be whoever the next
democratic administration is,
whether that's in four years or 12 years
or whenever it is, that I would appeal to you
to set that aside and understand that we need to build,
and this is a national security issue,
and that there are lots and lots of ways
that we can use those people to build even more.
There's a certain amount of bureaucrats in government who today I would say are sort
of governing an empire of dirt.
They're governing a whole lot of nothing.
And we have to peel that bureaucracy back to start building again.
But as we start building more and more and more, you're going to need to add people back
in because the industry is going to grow and it's going to get bigger and it's going to make more power. And there will be lots
of opportunities for bureaucrats to do the good work that they do in making things safe and checking
things out and those sorts of things. But you have to let the industry-
I've never heard anybody say, let the bureaucrats do the good things that they do ever in my life.
Well, let me counter this for you for a little bit. So one of the things that's very unique about American culture
is that we have had very functional bureaucracies
before.
Bureaucracies can do things.
They have a huge failure mode, which we all know now,
which is that they get slow, and they don't do anything,
and they stop progress, and they take 10 years
to do a single piece of paperwork.
But you can sort of think about some of the great engineering projects of the last 100 years as
bureaucratic projects to some extent. So the Apollo landings, landing on the moon, had bureaucrats.
There was a lot of paperwork involved in that. You had a lot of people checking designs, checking
document flow, ensuring security, ensuring,
you know, all of the things that go into checking the boxes to make sure that
nobody died on the moon, right.
And we had a successful outcome to that mission.
There was an army of people involved in that effort.
Um, and you would call many of those people, bureaucrats, lots of engineers too.
And I would say the ratio was a lot better, right.
The ratio of bureaucrats, engineers was a lot better.
But you really do need what I would say is people who dedicate their life to making the
machinery of government turn.
And so you do need that.
But you need to not let them run the ship, right?
Engineers need to run the ship.
And I would say administrations need to run the ship.
You need to have an executive who's running the ship. And I would say administrations need to run the ship. You need to have an executive who's running the ship.
And those people need to help the president run the ship in the right direction and not
become a thing that is purposeful in and of themselves, like the bureaucracy for the bureaucracy.
That's where it gets really bad.
My fear is, I mean, the country is very divided right now.
Has been for eight, 12 years, you
know, maybe longer.
Yeah.
Probably since 9 11, you know, it's just, it's
gotten worse and worse and worse.
And you see, you see, you know, Democrats come
in and they undo everything that the
Republicans did.
And you see the Republicans come in and they
undo everything that the Democrats did just,
just because the country's become so tribal.
And so, you know, my question to you is, you know, a lot of people aren't
going to be happy with how things are going.
Yep.
And this administration wouldn't be surprised if it flips.
Yep.
Wouldn't be surprised if that party undoes everything.
You know, the cycle just keeps continuing.
Right.
And so what my question to you is, are you building relationships with, I mean, I know right now we have, you know, we have a
Republican heavy house, we have a Republican heavy Senate, we obviously, you know,
president's Republican, you know, so if that switch, it might switch, you know, in a year and a half,
midterms, you know, are you building relationships with Democrat politicians?
Yep.
Yeah.
And I think the, the place where this mostly happens is at the state level, right?
So state level and somewhat in Senate and house.
Um, but I think that today Republicans are leading the charge on energy dominance.
And, um, I would appeal to Democrats that when it's their turn again,
that they should pick that up and do even better. Right? Like that's going to be the charge. And I
think that's how they'll win because energy really is something that's good for the American people.
And it's good for American interests. And people want to vote for that. They want to vote for
cheaper prices, for stable power, for security, for manufacturing, for
jobs.
All of these things are downstream of energy.
And again, I think the right sentiment was there, especially in the last Democratic administration.
Before that, I think previous Democratic administrations were a little bit anti-nuclear.
The Biden administration, I would say, was like pro-nuclear, but not willing to rock
the boat.
Mm-hmm.
Now the boat has been rocked, right? Trump just rocked the boat and we're charging forward. And
so I think that's a great tee-up for a Democratic administration to push that ball even further and
take that win. So that would be my appeal.
I think that's great. What I'm asking is, you know, are you developing the relationships that you need for when there is a turnover? Because there will be a turnover.
Yeah. You know, and so are you having discussions with, you know, Governor Newsom and your state
about about this? And yeah, I would say not so much in California, but in other in other
democratic states, yes. California, unfortunately, has a moratorium on nuclear and it's, you know,
may or may not be repealed. That would be awesome. But yeah, I think like there's some,
there's some shift that's going to have to happen and whoever's willing to run forward on that
shift. Nevada is a good example. Washington state is a good example of places where that
shift could take place. Illinois is having a moment where they're trying to figure out if they're going to be
pro-nuclear or not.
And so the short answer is yes, but Republicans have the ball today and they're running really
fast with it.
So whoever has the ball next and is willing to run with it as fast, I'm going to be very
excited to work with.
Well, I hope you build those relationships.
Thank you.
Yes.
You're going to need them. Absolutely. But Isaiah, kudos you build those relationships. Thank you. Yes. You're going to need them. Absolutely. But, uh, Isaiah,
kudos to you, man. Thank you. Like amazing what you're doing.
26 years old dropped out at high school at 16. I mean, and now you're,
you're building nuclear reactors. I mean, that is just
really cool, man. And variance and with your backstory, you know,
growing up, nothing came easy on food stamps to who you are today.
I mean that's inspiration for an entire generation.
Well, thank you so much for having me on. This has been a really great time.
My pleasure. Congratulations.
Thank you.
Hope to see you again. I'm not sure you're gonna like all of it.
Honestly, I don't even care if you like all of it or not. I have a job to do.
Scorching debates.
On any given week you have lots to beef about. Take advantage of it. Get up in here.
He's the Spitfire of sports smack.
This is not my fault. We will get to all of that.
The Jim Rome Show podcast.
Get up in here and we'll beef later on. What's your beef?
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