Natural Resources Committee on Feb. 5th, 2013

Yes, small modular reactors are a possibility. In the type of reactor we talk about, some of these inherent advantages are accrued only in the larger types of reactors. Ours tend to be in the range of a few hundred megawatts and above.

Our focus is on materials and fuels. Because this particular type of reactor does not have to be fuelled very often—in fact, in some versions the initial load of fuel will last for decades—it means that the materials and the fuels that are in the reactor have to be warranted to be able to withstand that environment for decades.

That is the emphasis of our research. There's lots of other stuff, but if I have to pick out the main technology that we're working on, it's that.

Yes, we have. They are preliminary. We have worked out with experts in the field a licensing plan and what sorts of things you would have to do to gain that licence.

One of the advantages we have is that very similar reactors have been licensed before.

To a prototype, it will take several billion dollars. That's what I can tell you right now, that it's in the order of $4 billion for a prototype. The research and design budgets are about a quarter of that.

Yes, they are. Right now we're in preliminary discussions with a number of companies.

First of all, our approach is not very small, but I'll be happy to talk about the proliferation advantages and safety advantages.

Proliferation advantage comes mainly from the fact that the fuel is left inside the reactor for some length of time. The proliferation advantage comes because eventually the reactor system can sustain itself without the need for enrichment plants. In Iran and other places, you know that's a problem. Because depleted uranium and natural uranium can be used as the fuel and used much more efficiently than previous reactors, you don't need to take the waste and separate out plutonium, make a new fuel and put it back in; therefore, one has eliminated the proliferation risk of reprocessing, as it's called.

Finally, you can take this reduced amount of waste that the reactor produces and put it directly in the ground. Some folks at MIT and Berkeley are advocating the use of the bore hole, which means you immediately dispose of the waste. So the infrastructure is so simplified and the number of times you have to refuel so reduced, the approach to proliferation is much more attractive.

When it comes to safety, the reactor operates at higher temperatures. This is not our idea; it's been put forward before. If you have a reactor that operates at these higher temperatures and something goes wrong, clever engineers can arrange a chimney effect basically that allows this coolant, which is very good at conducting heat, to dispose of that heat à la the chimney effect to an infinite heat sink, namely the atmosphere. You can screw up the operations, the operator can do the wrong thing or not, a wave can come and shut down diesels, but this thing will stay cool enough to be fine.

I'll start with the second first. No, no Canadian agencies have contacted us. I had experience decades ago with Canadians who were working on fusion and nuclear, but that's a decades-old experience.

We are trying to interest large companies in the United States, Japan, Korea, etc., in adopting this. Our plans are not to become a Westinghouse or a Toshiba; our plans are to influence the direction of nuclear in the world. We'll get something out of it, we hope, but we're hoping that the profitability presented to these large firms will motivate the sales everywhere in the world—China, eventually India, Africa, etc. You could ask what good are these reactors around small villages, but the fact is that villages in some parts of the world are huge populations. Our goal is to do this development and catalytic investment, which will influence the big players.

Right now the funding has been entirely private. It has been from Mr. Gates and other visionary investors. The government has been very supportive, helping us in ways it can to allow us to have discussions on a foreign basis as well as domestically. They've been very cooperative in making research samples and materials that they have worked on in the past available to us. They've cut through the red tape so that we could do that. The national laboratories have been very helpful because of the support from DOE.

But the funding, including most of the money in the national labs, has come from us. Eventually when it comes time to—

I think there is. We pay for CRADA's joint development things, but some of the stuff they've had available they've gone ahead at their own expense, whereas the specific tests conducted precisely for us have used our funds. But, yes, indeed, because we generated this interest, a true intellectual interest, in the labs, they've gone out of their way to do things for us as well.

Right now, of course, they're tax credits because we're not profitable. But my experience in the past with renewables, for example, and some nuclear stuff.... One of the great times in California, when I was doing this sort of work, was when the regulators would allow research to be an allowable expense for utilities. When that went away in California, it had a profoundly negative effect. This may be useless information to you, but I'm just giving you my own experience here.

I found direct funding from a government very useful if it was attached to an attitude that you're allowed to take reasonable risks for big rewards. That's typically not a government characteristic, unless it's declared clearly to be R and D, in which case, of course, you're forgiven for more give and take in the results.

I think the ARPA-E that DOE has going is a refreshing change from some of the ways I've seen governments fund things. Again, I'm speaking of my experience in the U.S. I apologize for having very little experience in Canada.

I don't know whether this is helpful.