The US Navy tried a sodium cooled reactor, but pinhole leaks in the hear exchanger allowed sodium to come in contact with water and create tiny explosions. I'm not sure why they abandoned the concept. Modern chemistry control should be ae to overcome the difficulties. The big advantage is that the sodium coolant doesn't need to be highly pressurized. A water cooled reactor needs to be kept around two thousand pounds pressure, and that leads to problems, and loss of coolant pressure could cause catastrophic damage and meltdown, as we saw at Fukishima. Sodium would help avoid that, but I'm sure it presents its own problems.

Relatively confident Gates has done his research.

I've said previously that "homes" is a misleading and even childish unit for measuring energy, but I also know that the average relatively innumerate "layperson" isn't going to be wrapping their heads around exajoules anytime soon.

Residential use accounts for close to 20% of the energy used in the U.S.A..

From that, we can conclude from TerraPower's own figures that one of these plants could support the entirely carbon-free middle class lifestyles of 50,000 to 80,000 U.S. Americans.

If we want to make the math easy, which I do, we might say that one of these reactors could support the basic necessities of clean water, healthy food, and comfortable basic housing for 500,000 to 800,000 people.

The Natrium website gives the obligatory nod to wind and solar power, which is always amusing. If you build enough nuclear power plants you don't need wind or solar power. The converse is not true.

Unfortunately it seems that any new energy resources are going to be used on Artificial Intelligence (or Idiocy, depending how you look at it) and new energy-intensive tools for spying on people.

the continued development of AI is going to require new power innovations.

(Approximate paraphrase.)


I hope this Wyoming project is a success.

by having the reaction moderated by molten salt instead of scarce to unavailable water. In addition, when you cut power to a molten salt reactor, it just slowly starts to cool and becomes nearly inert.

Unfortunately, there's another part to the problem, the need for water to run steam turbines to generate the actual electricity. While high temperature ceramic thermoelectric generation might be the solution, it's decades away, if ever.

One potential advantage of high temperature reactors compared to the lower temperature pressurized and boiling water reactors is that the condensers could be air cooled.

Conventional pressurized water and boiling water reactors require copious amounts of cool water for their condensers. Usually this water is drawn from rivers, lakes, or oceans.

The Palo Verde nuclear power plant in Arizona uses treated sewage water cooled by evaporation. An air cooled high temperature reactor would use much less water.

Were it not for the necessity of using steam turbines, I'd be liIn fact, the whole southwest all the way to California is littered with volcanic systems. What we lack is water. The little we have is needed to support wildlife, people, our animals and our crops.

That's why I'm following research into high temperature thermoelectric ceramics. Unfortunately, researchers in areas with a lot of water are stuck on steam turbines, so research into ceramics is proceeding at a glacial pace.