a16z Podcast - A Nuclear Comeback: Are New Reactors the Answer?
Episode Date: March 15, 2024Nuclear energy accounts for 20% of the electricity in the United States, but remarkably, 2023 marked the commissioning of the U.S.'s first new nuclear reactor in over three decades. The past few years... have been a story of changing public opinion, but equally, innovative startups crafting groundbreaking reactor designs and an ambitious announcement by the U.S. government to triple nuclear power production by 2050.In this episode recorded at a16z’s American Dynamism Summit in Washington DC, a16z podcast host Steph Smith is joined by a16z General Partner David Ulevich, Doug Bernauer – CEO of microreactor company Radiant – and Dr. Kathryn Huff, Assistant Secretary of the Office of Nuclear Energy.From energizing the country's data centers to propelling the electric vehicles on our roads or powering the factories crafting tomorrow's innovations, they discuss why expanding our nuclear capacity is a national imperative. Stay tuned for more exclusive conversations from a16z's second annual American Dynamism Summit in Washington DC. Topics Covered: 00:00 - The Promise of Advanced Nuclear Reactors03:43 - Nuclear Energy's Current Landscape07:00 - Vulnerabilities in Fuel Delivery10:30 - Nuclear Energy's Timeline12:11 - Portable Microreactors and Mass Production 15:06 - Nuclear Energy's Role in America21: 24 - Government's Role in Nuclear Energy26:08 - Challenges of Portable Micro Reactors 30:03- The Evolution of Nuclear Reactors32:11 - Nuclear’s Public Perception and Safety39:21 - The Global Need for Nuclear Power Resources:Learn more about American Dynamism Summit 2024: www.a16z.com/adsummitFind Dr. Kathryn Huff on Twitter: https://twitter.com/katyhuffFind Doug Bernauer and Radiant on Twitter: https://twitter.com/radiantnuclearFind David Ulevitch on Twitter: https://twitter.com/davidu Stay Updated: Find a16z on Twitter: https://twitter.com/a16zFind a16z on LinkedIn: https://www.linkedin.com/company/a16zSubscribe on your favorite podcast app: https://a16z.simplecast.com/Follow our host: https://twitter.com/stephsmithioPlease note that the content here is for informational purposes only; should NOT be taken as legal, business, tax, or investment advice or be used to evaluate any investment or security; and is not directed at any investors or potential investors in any a16z fund. a16z and its affiliates may maintain investments in the companies discussed. For more details please see a16z.com/disclosures.
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They recognize we have this insatiable need for energy.
We're not going backwards in our energy consumption.
So if we're going to have new energy generation, it has to be clean energy.
Deliveries of fuel are a clear vulnerability.
Natural gas obviously can hold an entire nation hostage.
The typical construction timeline is really like six to 15 years on the big reactors right now.
Maybe nuclear energy is a lot safer than we actually originally realized.
The radiation exposure from living next to a coal plant is high.
than the radiation exposure from living next to a nuclear power plant we can reduce the radiation.
The really exciting thing for me is that really far into the scale of portable microreactors,
we haven't really achieved that yet.
And you could actually produce these in a factory because they're portable.
You could do mass production.
10 or 15 years from now, the idea that we can't just immediately turn on a reliable and enduring power source for a community,
it's going to be unimaginable if it will be a solved problem.
What might surprise some people to learn is that nuclear energy accounts for 20,
60% of the electricity in the United States.
But what I think will surprise very few people,
it's to learn that this carbon-free energy source
has quite the storied history.
Over the last few decades,
resulting in new reactors slowing almost entirely to a halt.
However, the past few years have been what some people might call a comeback story.
In 2023, we saw America's first newly built reactor come online in over three decades.
But we're also seeing startups built entirely new types of reactors, public discourse shifting,
and even the U.S. government itself recently announcing its intent to triple nuclear power production by 2050.
So in today's episode originally recorded in the heart of Washington, D.C., back in January, at A16C's American Dynamism Summit,
we talk about this truly unique moment in time for nuclear energy.
A16C General Partner David Yulevich joins forces with Doug Brunauer, CEO of Microreactor Company Radiant, and Dr. Catherine Huff, Assistant Secretary of the Office of Nuclear Energy, as they collectively discussed nuclear energy's role in our country's future.
Because remember, energy is vital to many of the industries that we talk about here.
Energy powers the data centers that run our clouds, the electric cars that drive on our streets, and of course is fuel for the factory.
that build our future. So if anything feels certain, is that we're going to need more energy,
not less. So tune in here as this group of policymakers, founders, and funders discuss why
increasing our nuclear capacity should be a national priority and what it'll take to reverse
this multi-decade trend. Oh, and if you'd like to get an inside look into A16C's American
Dynamism Summit, you can watch several of the stage talks from the event featuring policymakers like
Congressman Jake Ockingcloss or Senator Todd Young, plus both founders and funders building toward
American dynamism, you can find all of the above at A16Z.com slash AD Summit. All right, let's get
started. As a reminder, the content here is for informational purposes only, should not be taken as
legal, business, tax, or investment advice, or be used to evaluate any investment or security, and is
not directed at any investors or potential investors in any A16C fund.
Please note that A16Z and its affiliates may also maintain investments in the companies discussed in this podcast.
For more details, including a link to our investments, please see A16C.com slash disclosures.
Nuclear has quite the storied history, and in the last 50 years in particular, progress has really slowed.
And I'd love to get your take, Dr. Huff, on the key factors that you really attribute to that.
Yeah, I think critically the expense of different kinds of energy technology typically determine
what utilities are going to select. And there was a serious period of time where, for example,
natural gas was an extremely cheap option to build quickly with low capital investment. And that,
I think, is the primary driver for a lot of reduction in the builds for nuclear. And then as you
lose that muscle, it becomes more and more expensive to get it back, right? Much like if you stop working out.
Yeah, and I think there's a lot of public opinion around nuclear. Some people attribute that to, again, that slowdown over the last few decades.
Doug, is there anything you'd add there and maybe other misconceptions that you think the public holds?
I think over the past 50 years, a lot has happened. Solar and wind technology really came about and was deployed, kind of in the middle of this nuclear story we're telling, and these forms of energy, but that are not resilient forms of energy.
and by the time we deployed them significantly to the grid,
we started to look for a source of power that you can scale,
that you can throttle up and down on demand.
And at the same time, scientists started to care about climate,
and then I think the public really has come around to really care about climate,
and not just to care, but to want to do something about it.
And so I think nuclear has this really cool new role to fill
instead of natural gas, which I agree with Dr. Huff.
The low cost of it definitely causes to adopt that,
to fill that need, rather than nuclear.
I think nuclear can leapfrog it.
Yeah, and I think we are seeing renewed interests, which is exciting, especially over the last few years.
David, what's your take on that?
Is there a really strong why now, and is it just climate, or is there another series of factors at play?
I think that we have this insatiable thirst for energy, and we have so many things that power the way we live
and the way we want to live and the way we want to work that require electricity.
And so we need all forms of energy to be increased, I think.
Some are better than others.
Some have a longer feature, I think, ahead of them than others.
So for me, nuclear is this baseload energy.
You don't need the wind to be blowing.
You don't need the sun to be out.
And it can be delivered in a lot of form factors.
And so to me, that makes it very exciting and really worth the investment in rebuilding
the muscle to use the analogy that Dr. Huff made earlier to really rebuild the muscle of how
do we build nuclear power plants and what kind of plants do we want to build and to power
what kind of loads and in what kind of circumstances?
And so I think that climate's a huge part of it.
Recognize we have this sensational need for energy.
We're not going backwards in our energy consumption.
That ship has sailed.
So if we're going to have new energy generation, it has to be clean energy.
And I think that there's also been a renewed interest in people getting reeducated as to
what are the risks and opportunities with nuclear energy.
And I think that's come from a lot of different places, whether it's from government or
from industry or from academia, that maybe nuclear energy is a lot safer than we actually
originally realized, and that it's really worth the time spent there to see if that's a viable
way to generate the kind of energy that we need in the future.
Yeah.
I mean, it's been a long time, right?
We're not in the same place as many decades ago.
There are new reactor designs, which we will definitely get to.
But Dr. Huff, I want to talk about your house testimony that you did recently, and you referred
to our current approach to nuclear as, quote, a national security.
vulnerability. And you reinforce that the Office of Nuclear Energy is doing a few things.
So first, keeping the existing fleet of reactors operating and online, deploying new
advanced reactor technologies, sustaining and securing the nuclear fuel cycle and expanding
nuclear energy cooperation. And something I'd love to get you to touch on is really that
role of nuclear in America's global standing and security. Thanks for that. And I think that
why now question ties to this. In the testimony, the particular component of our approach that I think
as an active vulnerability is the fuel cycle security.
But an additional piece is that energy security and energy resilience
that nuclear energy can provide to support those more variable sources to be on,
no matter what day it is, what time it is,
to not require refueling.
Consistent deliveries of fuel we've seen in, for example,
embattled Russia, Ukraine invasion,
we've seen that deliveries of fuel are a clear vulnerability.
Natural gas obviously can hold an entire nation hostage.
Deliveries of those sorts of fuel, since they can be interrupted,
really undermine the security of otherwise accessible and deployable sources, right?
And if you can not dispatch that power, then it's not useful to your resilient.
Nuclear power, on the other hand, even existing conventional plants,
they only need to be refueled once every 18 months, maybe two years, right?
And so they can run alone as an island for quite a while,
and this really underpins what we can see as an energy security
and energy resilience that, frankly, in today's geopolitical universe
represents our access to sovereignty as nations,
our continued operation as independent states.
The U.S. has a number of other features that make it
secure nation. But there are a lot of other countries that really can be threatened by another
nation that would use energy as a weapon.
Yeah. And we have many technologists building towards these new reactors and improving
that fuel cycle. But can you speak specifically to the government's role in that? What is the
government's role in securing that fuel cycle and that global cooperation while also ensuring
that we're getting these new reactors built in the USA?
It takes a lot of pieces, right? With tax credits from the Inflation Reduction Act,
and grant funding from the bipartisan infrastructure law,
were able to do things like encourage subsequent license renewals
to be economic for existing nuclear power
or, in the case of the bipartisan infrastructure law,
dollars advanced demonstration programs.
But the Office of Nuclear Energy's focus
has historically been on R&D programs,
the kind of R&D that takes startups like Radiant
and support technological advancements.
And through small grants, we've tried to expand
our support of as many companies as possible.
And there are lots of them, more than we could possibly support, actually.
And it's, I think, a feature of many decades of working through the national laboratories,
which we manage and operate from the Department of Energy,
and ensuring that we have a basis, a strong technological capability to support the kinds of scientific explorations
that we need to propel those technologies forward.
So let's talk about some of those new technologies.
Doug, let's throw it over to you.
Can you actually just break down the different generations of reactors and also where we've come, right?
As I said before, it's been several decades.
Where are we now in that technology?
I'm going to ask Dr. Huck to correct me on anything I get wrong here.
I'm actually not an expert in all the history of nuclear and every kind of reactor that there is.
I'm really an expert in what I'm doing, which is portable, high-temperature gas reactor.
But the generations, roughly, people use these gen 1, 2, 3, and 4 terms.
Gen 1 are really the reactors we first figured out.
They're kind of pre-enrichment.
They're usually like a graphite-moderated reactor.
And then Generation 2 reactors were very different because we started to do.
enrichment with these big gas diffusion enrichment plant. And in that time period, the U.S.
was really at the forefront of everything. I think we had over 400 uranium mines operating in the
U.S. And really, we were the great developers and exporters of our technology to the rest of the
world. And then Gen 3 really are meant to be an advanced form of those Gen 2 reactors
that can make use of enrichment. And they're like accident tolerant fuels or ability to recycle
fuel. They're kind of these advanced features. And then Gen 4 is really meant to represent these things
that are much farther away.
They're kind of future that, like, they perfectly produce hydrogen, let's say, and make
a hydrogen economy possible.
That's pretty good.
I would say there's one interesting nuance that, you know, a lot of the conventional reactors
that are operating today are in that Gen 2-3 space, but there's Gen 3 plus that people sometimes
will introduce this language and what does that really mean?
And who knows?
It's like something in between Gen 3 and Gen 4 where you're incorporating modularity in the construction,
but it's still a light water reactor, for example.
And so we see a lot of different definitions, but I think you did a fine job.
I have my own scale.
I like, this is kind of interesting.
Thanks.
So you have like big reactors, right?
They're a gigawatt.
They're for a million people or a million homes, let's say.
So it's more than a million people.
This is kind of the right scale.
And then we've got SMRs.
And the purpose of SMRs is really to take that big reactor and build it really fast.
Okay.
And the typical construction timeline is really like six to 15 years on the big reactors right now,
depending who makes them, even for the exact same.
same reactor, like an AP-1000. Built in the U.S. is very slow. Built in Asia is very fast.
But you can make the reactor smaller. You can make it faster. The idea behind an SMR is to
make something that's maybe for about not a million homes, but maybe about 250,000 homes, right? A quarter
of the size, but be able to build it really quickly. And if we could achieve that, it would
be a great economic success. But the spectrum is getting longer and longer. I think one of the
interesting things happening now is looking smaller and smaller and looking at microreactors.
And there's kind of two categories of microreactors, portable and non-portable.
And if you do a fully portable microreactor, this is around the scale of 1,000 homes.
So it's 1,000 times smaller than the reactor all the way at the other end of the spectrum.
And you have microreactors which are not portable, which are 10 or 20 times larger,
maybe like 10 or 20 megawatt electric, something like that.
The really exciting thing for me is that the really far into the scale of portable microreactors,
we haven't really achieved that yet.
And you could actually produce these in a factory because they're portable.
you could do mass production and then ship them around and very quickly deploy them in all these little areas
where you have equivalent of a thousand homes, which could also be like a workplace that has 2,500 people, a mine, a military base, a hospital in some key kind of remote region.
So I like this scale better than thinking about the advanced ones, more about deployment and like how can you put them out in different areas.
Maybe we can talk about the use case, right?
So when we're talking about, let's say, a military base, what is the current state, right?
If we're not using these micro reactors, what is being used today and what's the tradeoff there
if we can actually get to that future reactor?
Current state at the military base is that they have backup generators.
Any site that has critical infrastructure, those backup generators will have diesel storage tanks.
There'll be 40,000 to 150,000 gallons of diesel on those sites, and they'll only use it
in a backup scenario, so it requires they put batteries all over the installation.
And if there is an outage, they're typically going to run out of that diesel, especially if there's, you know, something like the Colonial Pipeline Ransomware attack where we lost an ability to move fuel in a huge multi-state area.
And they ran out of fuel before their time frame, which is usually a 14-day resilience time frame.
So they've got a problem, and they're looking for solutions, and they're actually very interested in both categories of microreactor, because those are around the scale of the base, all of the larger ones, an SMR or a gigawop class reactor would be too large.
David, let's bring you into this conversation.
Obviously, we've invested in Radiant, and I want to get your sense of where you see capital being deployed in this new ecosystem as new reactors are coming online.
What's the opportunity here, and where do you see, again, some of those private dollars actually being deployed to?
Yeah. Both Doug and Dr. Hufft touched upon some really important points that relate to why having modular or just numerous points of energy generation spread across our grid and possibly amongst our allies is really an important concept. Because I think we touched on it, but for people that are not spending all their time in energy, it may not be obvious why energy and defense or in national security and sovereignty are really, really interrelated. I'll just give one example. Take an island, kind of.
like Taiwan that does not have its own energy independence. You can imagine a blockade of a
country like Taiwan where coal, oil, or other fuel sources that are normally supposed to go
deliver fuel to the island are prevented from reaching their ports. At that point, a country like
Taiwan may only have a week or two or three weeks of fuel on the island. And rather than having
some kind of a kinetic or war on Taiwan, a blockade would just be equally, potentially as
devastating. You can imagine hospitals running out of their generator supply, military bases,
not able to turn the lights on. Runways have no runway lights. I mean, it cascades from there.
And just all the infrastructure eventually just quickly starts to fall apart. And so that same
example actually applies to the U.S. We do have lots of geographic things that protect us as a
country. We have two major oceans on both sides. We have lots of resources. We obviously have
our own fuel supplies. But our grid is very brittle. There's multiple ways to make the grid more
resilient. But one way is just adding capacity in distributed fashions so that when there are power line
issues or fuel transfer issues, you're not totally reliant on these major sources of power or for
fuel to power entire parts of our country. And so that's just critically important that we
increase the resiliency of our grid by adding redundancies in lots of power generation. And if we
are able to do that by creating these more modular reactors, even if they're not mobile, but modular
reactors. One of the issues with nuclear historically is that it costs a lot of money to build,
not just time, but a lot of money. One of the reasons it costs a lot of money is we don't
actually make that much of it. And if we made more of it and we sort of developed that muscle,
the idea would be we could make more reactors more cheaply. And by doing that, we could place
them in strategic places across the country, make sure they're close to our key Air Force
bases and military bases in places where we need really reliable and enduring energy.
So that's why it's so important for national defense and for security and why our allies
care about it as well. No country wants to be totally at the mercy for energy of other countries.
And so that's important. So did I say anything wrong there?
Perfect. Okay. I think I got that right. I heard deploy more.
Deploy more energy. More power. Yep. We didn't even talk about data centers. But we're going
through an AI revolution right now. And it's going to bring lots of cool apps to our phones and
our devices and our new vision goggles or whatever. And all kinds of new devices we don't even have
yet. Our cars are becoming electric, and we got to charge those things up. And so all those things
need power. And so we just need way more resiliency and way more capacity on the grid. And again,
that's going to come from lots of ways, but nuclear is a really, really good way. That's why I think
this is much more palpable energy. As we get these new reactor designs coming into this ecosystem,
is there a new play? Is there a reason why now private dollars are interested?
I think the national lab system, which is really a unique and special thing about America,
Other countries have things that they try to replicate the national lab system,
but there's nothing quite as robust.
And the national lab system has many roles,
and Dr. Huff can speak to this better than I can,
since I think she helps oversee the national lab system in her current role.
But not only do they provide research,
but they're actually part of the supply chain of fuel for nuclear power plants.
They provide grants and funding for private industry to work on nuclear reactor designs.
There's a competition element that the national lab system from the DOE fosters.
And so that has been all wonderful, but I think that we have noticed that there's an opportunity to be an accelerant to what's happening in the national lab system, which is closely tied to academia, to say, hey, look, maybe there's a commercial opportunity.
And actually, maybe it's possible when we think about all these data centers that people want to build.
And we think about the fact that a lot of utilities are private, even if they're regulated, they're private companies.
Maybe we could say, hey, look, maybe there's an opportunity to really jumpstart a different kind of power industry.
And that's a bet that we're willing to make.
We think that there's tailwinds from a regulatory standpoint.
We think there's tailwind from an economic standpoint of building reactors.
There's a talent tailwind.
So Doug worked at SpaceX.
When SpaceX first started, there was only one company that really reliably put things into space.
There was NASA.
And now we have SpaceX doing it so often that it's almost a non-event now
when they launch satellites into space and rockets into space.
And we think the same thing can be true with nuclear.
And it doesn't seem like the kind of market where
only one company can win.
As Doug mentioned, there's all kinds of different approaches
nuclear for different use cases.
And so that's pretty exciting.
And I think that since our investment in Radiant,
what I've discovered is that there's a huge amount
of what I call downstream capital.
So other investors who have larger pools of capital
that are maybe not as risk-tolerant
as we are in Dresen Horowitz,
but who want to do project financing
or who want to fund large-scale capital projects,
they're very interested.
And then companies like Microsoft have spun up nuclear energy teams to figure out how do they procure energy that comes from a nuclear power plant.
And so that to me just says it's unclear exactly what the roadmap is going to look like.
I think my two colleagues here will know better than I do.
But there's just a lot of momentum and enthusiasm for something that we know is possible.
There's no scientific risk.
That's another important thing is we invest in all kinds of things.
There's no scientific risk with nuclear energy or minimal.
We know how it works.
And we have for a while.
Yeah, we've known for a while.
We can come up with better designs and better programs.
and we need new kinds of fuels, but we know how it works.
It's not science fiction.
Science reality.
Yeah, it's science reality.
Yeah.
So that's why I'm excited about it.
And that's why I think there's a lot more capital and interest in it now.
And the people recognize it's a predicate for everything else we want to do.
Yeah.
I mean, something you mentioned several times there is the economics, and even you talked
about space and that whole industry being rethought due to the economics fundamentally shifting.
So can we talk about that and the role of regulation in impacting some of these projects?
I think a lot of people cite Vogel.
as a project where the economics were far out of proportion, at least relative to the original
project plan. And a lot of people think that's an example of where people aren't willing
to invest in nuclear. Dr. Koff, can you just speak to maybe how regulation plays a role in
enabling some of these projects and whether any of that is changing or maybe whether Vogel is
an outlier? How do you think about that? Vogel, in a very real sense, is a first-of-a-kind build.
as was already mentioned, those AP-1000s can be built faster in different environments,
but those different environments aren't different just because of regulation.
They are also different because of the workforce capacity available.
So you look at a Chinese build of an AP-1000 and compared to Vogel,
and they had real differences in the sort of workforce availability.
And I think that's one of the longer polls in the tent,
not to divert from your question about regulation,
but I do think the Nuclear Regulatory Commission does an incredibly good job
keeping nuclear reactors operating safely.
They have an incredible safety record here in the United States.
And the NRC makes sure that that's true.
It makes it easy for me to say nuclear power is safe.
It's going to continue to be safe here in the U.S.
U.S. nuclear technology is some of the safest in the world,
and people should import it rather than some different technology.
And we know how to do it well.
It can increase timelines.
It can increase costs.
But I think even more critical is going to be workforce and supply chain issues.
that can delay the deployment of mega projects.
So regardless of whether you're a nuclear reactor that you're building
or whether you're looking at building a bridge or a highway system or a rail line,
these mega projects in the billions of dollars take years.
They sometimes take significantly more time than they should.
And each day in a project like that is another day
on which you are holding billions of dollars of capital
and not making profit.
and the cost of capital then starts to play into the total cost of the project.
And so the timeline on which you can deploy a reactor depends on, yes, regulation,
but also workforce availability and supply chain issues and simple project management
that adding up all of these things, the U.S. has lost this muscle being able to do this
efficiently in these big megaprojects, whether it's an airport or a nuclear reactor.
And by executing vote goal, we have succeeded at getting there,
with some reactors. I mean, the Vogel Unit 4 will turn on in a few months. Vogle Unit 3 has
turned on and is providing clean power of the people in Georgia. And in the course of doing so,
it has ensured the availability of some supply chains around nuclear. It has trained
thousands of workers that are otherwise excellent skilled crafts workers and are now nuclear
trained skilled crafts workers, electricians and boiler makers and welders and everyone else,
all of the building trades and et cetera. I mean, they had peaks of
of staff on site, around 8,000 people.
It's a huge number of people on site building a reactor.
Union crafts workers from 48 states.
And so that is the thing that I would point to
as something that I would worry about
in the longer term around the profitability of reactors
is that we've now shown that AP-1000 can be built.
If you were to replicate that particular reactor,
you should see some learnings, right?
Because now you've got a bunch of workers you can draw,
and you've got some supply chains you can draw on.
But so, too, can all the other reactor companies
that are planning to build new technologies.
They'll share some of the supply chain.
They'll share some of the workers.
And if we don't do it tomorrow,
a lot of those workers will go and build wind turbines.
They have other things to do.
This is a really tight environment
to have enough skill set
for the kinds of builds we need to do
across the energy space, not just nuclear.
So is that what you would point to, that workforce?
If we could accelerate this,
I mean, all of it comes into play here,
but it's not so much the regulation,
but ensuring that we have that workforce.
Is there anything we can do to improve
that outlook? Yeah, I think a focus on trade schools instead of merely universities. I say this
as a former and future university professor. It is absolutely important that trade schools and
community colleges and union training programs all be stood up at the capacity we need for
nuclear builds, wind turbine buildouts, solar panel buildouts, the kinds of transmission buildouts
we're going to need. And regulation certainly can get faster, but I would focus instead of
lowering the standards towards sort of lowering the barriers and accelerating the process.
Doug, obviously you're building in this space. How do you think about those relationships,
whether it's with regulators or with the large workforces that are needed in some of these cases?
How do you think of those relationships becoming productive?
So I think what Dr. Huff was talking about, I want to connect a little further.
So a really big plant that was built like that is amazing. It's awesome.
and all that workforce that we trained
and I think that can apply across
this entire spectrum of the different reactor sizes
that any successful project
should be cross-pounding that other
projects and it's not just from regulatory
sense but from just gaining that experience
that learning by doing and getting the cost
to be lower. So
I'm excited to be part of that way down at the tiny
end of the spectrum where our reactors
are 1,000 times smaller
but the regulatory environment
does need to change
and I think we were already working on it
There are a bunch of NRC modernization efforts coming by direction through Congress.
We've been working on developing things like 10 CFR 53, and that will be an ongoing and continuing effort.
But I think for it to really succeed, we need reactors to get built, to get fueled, to demonstrate,
and the DOE, to a large degree, are already fully supporting that.
Just for the audience, can you break down what some of those changes are?
Well, I think some of the changes are really just broad spectrum.
We don't have reactors that are this small that can be built in a factory.
I'm just going to talk about portable microreactors only for us to succeed at doing that.
Our timeline has not changed since we started a company in 2020.
We want to do a fuel demonstration in 26.
We're going to go through DOE authorization licensing, this path that exists at the national labs, to go faster than normal,
to do a test reactor at a test facility where you've got all the national labs support,
the expertise, the poster radiation experiment labs.
We're going to do that with our first unit.
Our second unit, though, needs to go through NRC licensing.
And so we've got to staff up in our little 45-person company
for these parallel paths to support going along both sets of regulations.
And I think the two could be actually woven together in a really practical manner.
And I know that people have thought about this for a while,
we just haven't achieved it.
So that's one of the things we could do.
But we've never cited a factory to mass-produced reactors.
What's funny about that is the regulations actually exist.
If you go look at like the original code, 10 CFR-50 has a thing called a manufacturing license.
It's in there.
and unused.
How many manufacturing licenses are there currently?
Zero.
There's zero.
It's never been used.
Well, in the U.S.
This is just U.S.
Yeah, for a reactor factory.
There exists no such thing.
Sounds like a good idea, though.
Yeah, yeah.
This is the only way a microreactor is going to get to the economics, right,
is if it's built more like airplanes there.
Like an assembly line.
Absolutely.
So we've been looking at that code, learning about it,
figuring out what our questions are, talking with the NRC.
Actually, our colitis microreactor is now officially in pre-application.
pre-application, only very recently. We're on the NRC's website. They're planning for us in their
budget so we can get that sorted out on time. So we'll be citing a reactor very quickly. We want to
deploy a unit in 2028. But I think that's enough to unpack around regulations. We're going
to build our unit with as much support as we can gather. We're not going to change our timeline.
And we started to feel real support from the DOE. I want to say thanks for the support we have
that we're working with Idaho National Laboratory. Radiant is committed to being ready in 2026 to go
into the dome. There's an old experimental breeder reactor dome that was converted to now
do these microreactor demonstration experiments. A lot of work and effort and funds have gone
to build that structure and we're still on target and ready to go use it as soon as it's
available. It's so exciting, actually, this feed study that Radiant is doing. They're in the
first set of three companies that are going to tell us exactly what they would do inside this
former containment structure that housed one of the coolest reactors we've ever built out there.
in Idaho, that reactor is over, and now there's room for new reactors to try things out
in a safe sandbox. Yeah, and I know we're early stages, but this picture of an assembly
line of reactors is one that a few years ago might have sounded outlandish, but now
there are builders creating this. Where will we be, like, let's say, in a decade if this
does come online? Can you just paint a picture, Doug, of where these reactors could be deployed
and how maybe broadly they might be deployed and the use cases for them?
Yeah. So we'll start the 10 years in 2026. So ideally we fuel and demonstrate at full power in the dome. And then by 2028, we have one commercial unit just a few years later. To do that, we're really running two regulatory efforts in parallel. And then three units in 2021, eight units in 2030, scaling on up until we're at 2036, we should be making 50 units a year. A reactor a week coming off a line. And the reactor we're developing, it's a heavy unit, but it can fit in a C-17 aircraft or on a truck. And you can
move it around, get it wherever it needs to go in the world. The optimal use case is really
replacing some diesel generators. And then a reactor lasts for five years, approximately out
in the field, and then it's shut down, and then we bring it back to that factory to refuel
it. So it is not only a new reactor construction factory, but a line producing a bunch of
new cores and a refueling facility, all co-located on the same 25 acre or so plot of land.
And so what we would do is have a population of about a thousand of these out in the world
because we're planning for a 20-year licensing time frame.
So you've got the 50 a year and about 20 years they last.
And so there's kind of a thousand of them that we can go and put in the thousand most important places that there are.
So these are like North Slope in Alaska, these really remote communities,
the ocean freezes up for them and they have to store huge amounts of diesel
and can't get new over the winter, so you've got to plan ahead and have enough.
And even when they can get new,
The price variability is incredibly unjust.
Give us a sense of that.
Like, how much can price vary?
They can fluctuate by an order of magnitude,
and you can't plan ahead for your family's budget.
If you have to be planning ahead for diesel power,
the changes on the day-to-day timeframe on the market,
especially in a geopolitical situation.
Letting a town lease a reactor for 20 years is very doable.
Yeah.
And it just dawned on me, as all of you were saying that you might imagine
that people in the public might think,
oh, I don't want a reactor in my backyard,
But at the same time, in this scenario, you could imagine that this Alaskan town would beg for that, right?
We don't want this variance.
Like, please give us this reactor now.
I think a lot of people would want a reactor near them.
Maybe not in their literal backyard, but I think that's mostly because they'd rather have a pool, not for any safety-related reason.
But I think they want one near them.
A heated pool.
And I think that if you're in a natural disaster area and you're hoping that FEMA is going to come in,
and they might come in and provide you some tents and shelters, but it's very hard to provide power.
in a real serious natural disaster, whether it's wildfires, whether it's hurricanes.
And the two things you need immediately after disaster, clean water, and you need power.
And you can't do clean water from a generator.
It takes way too much fuel.
But you can do clean water from a reactor.
You can hook up a reactor to something that will clean water very easily and provide
people with the water they need to survive and with energy.
And that, to me, the fact that you can bring that in on an 18-wheeler is just supremely
powerful. And there's nothing like that today that exists in the world. And the number of lives
that it could change is tremendous. So separate from all the defense-related national security
related things, that's just one more example of many, of where having the ability to quickly
truck in or fly in reliable and enduring power is, to me, you ask 10 years where we're going to be,
10 and 15 years from now, the idea that we can't just immediately turn on a reliable and enduring
power source for a community, it's going to be unimaginable. It will be a solid. It will be a solid.
problem. Not only is it a mass-produced reactor you can truck in, but you can truck out. So this use
in FEMA, like for temporary use, is perfectly what the kaleidos microreactor is designed to do.
Reactors don't carry themselves away and everything that was radioactive can be fully removed
just on a normal truck and you leave a green field the day you leave. That's never been seen
before in nuclear. I wanted to share that point. Yeah, you can take it and move it somewhere else.
Yeah. Yeah. It's a brilliant application. I mean, people see these United Rentals trucks
around that like when you go to a concert, there's like the big United Rentals thing that's
got this big generator and it's like makes all the noise. Yeah. It's like, look, we can just
have United Rental reactors. Why not? That's actually what we ran when we did the Hyperloop
project at SpaceX. I was in charge of all the electrical work for it. We rented a big diesel
gens and that ran this futuristic tube that we pumped down to vacuum and ran vehicles at 350
miles an hour in. But it could be at every use. Talk about this Alaskan town. There's one more
thing that really motivates me about what we're doing. In a lot of places, they use diesel generators
only for prime power. The health implications of that are dramatic, right? A diesel gen set operating
of, of course, will produce CO2, but more critically, more importantly, it's producing carcinogens,
fumes that people are breathing in that area. They're breathing carcinogens. And if you look at
what happens in a town over 20 years span, if you pick a diesel gen set instead of a reactor,
there's something like 12 deaths that are going to occur prematurely
from the use of diesel, normal, natural measure
just at a rate ending people's lives prematurely.
So that's one of the things that really motivates me.
And on the regulatory side, I think we've got to think about that case.
I think we've got to make it possible at some point in the future
for the decision makers in the town, this theoretical little town,
to be able to pick the nuclear reactor,
the clean technology that's going to save lives
and to have an equal bar for regulations so that they can pick it.
Because one of the barriers right now will be the regulations for nuclear
are very challenging to cite these little reactors.
And it's because they don't exist and we haven't planned for it yet.
But that's what I think we need to start working on now,
so that 10 years from now, that future is achievable.
And when we think about these communities,
just so we can attack this question head on, Dr. Huff,
can you just speak to waste?
That's something that comes up a lot from these reactors, old reactors.
do we have a way currently today to safely store nuclear waste?
Yes.
This is a technically solved problem.
Right now, all the spent fuel is stored safely where it is.
It's a solid.
It's not a glowing green goo.
It's a ceramic.
It's more like a teacup, right?
Now, defense waste is a distinct thing,
but the commercial nuclear fuel in this country has never caused any radiation harm to humans.
it is stored safely in either pools or in dry-cast storage. It is, however, at 70 locations across the
country in places where the Department of Energy promised to take it off of their hands. They didn't
intend to store it there for the long term. And while it is safe for the long term as it currently
stands, it is the Department of Energy's responsibility to take it and consolidate it into one or
more consolidated interim storage sites to reduce the number of communities that live near those
facilities that they didn't agree to in the long term. And so we're working through a consent-based
process to identify locations that would be amenable to this. It's a really exciting process
that worked really successfully in Finland to cite a whole final repository and is working
in Canada. They're down to two sites for their final repository, which is much more complicated
than an interim storage facility. So it's our responsibility to do. We're doing it. There's no
technical question about, is it possible to safely store Spend Nuclear Fuel? We do it every day. We've
continue to do it. We transport spent nuclear fuel safely across the United States. Successfully,
no problem. I will say, just to expand a little bit to going back to this sort of what does
the future look like 10, 20, 30 years from now, right? In addition to microreactors saving the world
at the sort of edge of accessibility to power, at the edge of viability of other options, right
where diesel generators might sit at the edge of that small size scale, we also see real
opportunities to directly replace one for one. Coal facilities, right? Unabated fossil facilities
across the country represent a real opportunity for those 100, 200, 300 megawatt units, even bigger,
and they should be a real boon to the communities in them. Because interestingly, the radiation
exposure from living next to a coal plant is higher. The radiation exposure from living next to a
nuclear power, we can reduce the radiation. There's no emissions from nuclear power,
and emissions from unabated fossils actually can really include a lot of heavy metals and whatnot.
We're in this place where I think it's really important that communities,
especially communities around retiring and retired coal sites,
can have better health outcomes,
just like what Doug was saying about microreactors in diesel.
The same can be said about small-modular reactors and larger-scale fossil plants,
and that motivates me too.
When we think about the 200 to 300,000 premature deaths,
every year caused by pollution, unnecessary pollution, most of which is from power generation,
we can save those people.
Yeah.
So it needs to be addressed at every scale.
It turns out that burning trace radioactive materials and releasing them and these other
energy forms is much less safe than nuclear waste, which is kept in containers and shipped
and moved safely.
Yeah.
And has caused no accidents.
Absolutely.
Well, maybe to come full circle, Dr. Huff, in your recent testimony, you mentioned that
recently at COP28, the U.S. and 24 other countries signed an agreement to triple nuclear power
by 2050. That's very exciting, but it also sounds quite lofty. And so what do you really think
needs to be in place? We touched on some of these things, whether it's regulation, the workforce,
etc., public opinion. A lot of these are shifting in terms of tides as well, I should say.
So what's your take on how we actually achieve that goal and reverse this multi-year trend?
Yeah, let me be clear. These 24 countries signed together, just,
say, we recognize that we need to get to tripling nuclear power.
We didn't say we knew it would be possible.
I think the agreement here is that we recognize that there's a gap that has to be filled
by clean firm power, and that gap is gigantic.
And a huge fraction of that gigantic gap must be filled by nuclear power or else we're
never going to get to net zero.
And so this agreement is that the intergovernmental panel on climate change, the IEA,
the IAEA, et cetera, have all done a bunch of studies.
We, our individual countries have done studies about what it's going to take to get to net zero,
going to take tripling nuclear power. How do we get there? We are going to have to build new
nuclear power at a rate unparalleled. Now, not so crazy dissimilar from the rates of
gigawatts we added in the 70s and 80s, actually. It's been done before. It's been almost done
before. If we don't start tomorrow building reactors, then the rate goes up. So importantly,
if we don't build any new reactors next year, then we're going to have to build slightly more
every year between now and 2050.
So the slower we are at startup,
the harder it's going to be
to build out a supply chain appropriate
for building the number of reactors we have to build.
If you wait until the last minute
to do all your homework,
you have to write a whole essay in one hour.
But if you spend the week ahead of time,
then you only have to write a few words a day.
That's the situation we're in.
We have a little time,
but we have to start tomorrow.
We cannot wait until the last minute.
I think there's a couple points you brought up
that I think about a lot. One, you mentioned the supply chain for nuclear energy. We need to be
the source of fuel right now. America is a source of nuclear fuel, but there are other countries
that make a lot of nuclear fuel. And I think about our American dynamism practices, investing in
companies that support the national interest. One of the things that I think is in the national
interest is to be the premier source for nuclear fuel for not just the U.S., but also our allies.
and that's something we can do, and we certainly could do,
much like, I think, storing spent nuclear fuel
or recycling nuclear fuel.
Some people have this.
There's atmospherics around it, like PR atmospherics,
and people are like, oh, I don't know if I want that.
They ignore about all these other things they have in their backyard,
and they're like, oh, but that sounds bad because I saw a commercial once,
where I saw The Simpsons.
Exactly.
And they don't want the fish with three eyes, which is not a real thing.
And so I think we have an opportunity to really invest in the supply chain
for nuclear resources and nuclear fuel.
And I think it'd be really cool to see something kind of like the Chips Act for nuclear.
First of all, I think it would be a very bipartisan thing in this country.
I also think it's something where we could really encourage investment abroad.
There are a lot of countries that would love to have more nuclear energy, as Dr. Huff said.
And I think we have an obligation to be a leader there.
There are things called one, two, three agreements that I believe the State Department oversees today
that sort of regulates the amount of nuclear information and nuclear sort of business that we can transact
act with certain countries, but it's still an onerous agreement, and there's different standards
to that agreement, and there could be a real national priority put on elevating those standards
or making them more accessible or disseminated them more widely, and especially if we're the
source of nuclear fuel for these countries, it still gives us the levers of control that we
want to enable countries to have more nuclear power, but in a way that we think is safe and
reliable and represents the interests of our country. So that's something I would love to see
more of us. I do think there's some regulatory improvement that is gaining momentum here and we want
to see more of. I also think there can be a much larger international focus on America exports all
kinds of technology. We export defense products. We export all kinds of things. And there's no reason
why we shouldn't be exporting more nuclear reactors. And we do, like AP 1000, but we can be doing
much more. And that to me is an exciting opportunity, at least when you think about the commercial
aspects, that it's not just the U.S. that has this insatiable need for energy, but it is a global
opportunity.
Absolutely.
And if we don't do it, I think that other countries will.
Yep.
I guess that's the flip side of it.
Right now, for instance, there's a country that very much would like nuclear reactors
for energy, and the U.S. is not allowed to sell into that country, and currently the only
other country bidding on a reactor is China.
And I just think it would be better if we could bid in that country also.
Absolutely.
Doug, anything you'd add there in terms of, you could say, a wish list, you're building in this space,
and there are so many different factors that come together.
What do you hope to see, whether it's the supply chain, the workforces, the regulation?
I'm thinking, we talk very long term.
I'm thinking much more short term about my wish list because I have a very tight schedule.
Operating in the dome is just two years away, 23 months.
I need to make sure I get access to fuel.
Something David mentioned is really challenging, and OutDrop has been helping.
We talk about this regularly.
and I appreciate it.
It's hard.
But it's still a challenge for us.
I think a real microreactor demonstration program
from the federal side
would probably be the single biggest thing we could do
to accelerate our efforts to commercialization.
And I think that would help cross-pollinate
every other project that we have going on.
Dr. Huff, I'm going to close with you.
Anything else you'd like to share with the folks in the room,
but also we have so many people listening
who may have varying degrees of education on nuclear,
the state of it in our country, what would you like to leave people with about the years ahead?
Yeah, I think there's an incredible amount of money to be made. There are lives to be saved.
There is democracy to preserve sovereignty to deploy abroad. And we have, unquestionably,
some of the best technology in the world. That's American design. It's an American invention.
We are the first nation to ever sustain a fission chain reaction on purpose.
We have the largest nuclear fleet in the world.
We are poised to lead this as we transition into a cleaner energy system.
But we have to see private industry step up and say,
I will be the first to sign a contract, build the next radiant or whatever.
And I want to see as many contracts on the books as possible in the next couple of years
or else we are going to have a much bigger supply chain challenge in the next 20 years than we have today.
Every few months that are delayed between now and the order books that we need to show that deployment,
the harder it's going to be to build out as much as we need to get to net zero.
We have to get to net zero.
Full stop.
Not only have we promised the world, we're leading the world.
And I intend to still be around in 2050, and I'd like to be able to breathe.
Here, here.
That's a great place to end off.
Thank you so much.
We thank Dr. Huff, I think for her efforts in DOE and really pushing forward.
I would say a renewed and re-energized attitude towards nuclear policy.
It's, you know, innovators like Radiant and others that are really leading the way
and give us some good work to work with.
Well, I mean, I think that's why we brought all three of you in, right?
We have all sides of the equation.
We have the funders, the builders, and the policymakers all in the room
because that's all required for the future.
Now, if you have made it this far, don't forget that you can get an inside look into A16Z's
American Dynamism Summit at A16Z.com slash 80 Summit. There, you can catch several of the
exclusive stage talks featuring policymakers like Deputy Secretary of Defense Kathleen Hicks
or Governor Westmore of Maryland, plus both founders from companies like Andrel and Coinbase
and funders like Mark Cuban, all building toward American dynamism. Again, you can find all
of the above at A16Z.com slash 80 Summit. And we'll include a link in the show notes.
You know,