Guest essay by David Archibald
It is a significant fact that half the protein the world eats has its origin in fossil fuels. We are all aware of the green revolution that, amongst other things, saw dwarf strains of wheat increase yields by a couple of hundred percent. There was another revolution in agriculture sixty years prior to the green revolution. That was the development of the Haber-Bosch process of combining hydrogen and nitrogen to produce nitrogenous fertiliser.
The plants that produce that fertiliser, the source of half of the protein we eat, run on natural gas or coal. One day these fossil fuels will run out. Does that mean that half of our population starves? It does if we don’t have a way of producing nitrogenous fertilisers cheaply using something other than natural gas or coal.
And it won’t be sunbeams or wisps of the wind that will keep people fed. Those things barely pay for themselves, if that. Take the case of the Ivanpah solar facility in California built at a cost of $2.2 billion. Rated at 392 MW, Ivanpah is a near 20-fold scale up from the previous largest solar thermal facility of 20 MW in Spain. Despite all the engineering that went into the design of Ivanpah, it operated at least 40% below design in 2014.
The chief economist of the International Energy Agency, a warmer by the name of Fatih Birol, once said ‘One day we will run out of oil, it is not today or tomorrow, but one day we will run out of oil and we have to leave oil before oil leaves us.” What is true of oil, the liquid fossil fuel, is also true of the solid, coal, and the gaseous form, natural gas. One may quibble about the detail but the overall effect will look something like this:
Figure 1: Fossil Fuel Production 1800 – 2300
Oil production will be the first to start the long decline to oblivion. We can fix the problem of declining transport fuel availability by a form of alchemy that converts coal into gasoline, diesel and jet fuel. And we will be doing that. But it will be another short term fix until the coal runs out. You might think we have a lot of coal. We had a lot of oil too, once – until we burnt it. Converting coal into the transport fuels we need will double the rate of our coal consumption. And our coal endowment will be largely gone in our grandchildren’s lifetimes.
If we combine the data from Figure 1 with world population growth, we get this figure:
Figure 2: Per Capital World Fossil Fuel Production 1800 – 2300
Per capita fossil fuel production falls off a cliff in 2030. Projections of agricultural land available to be brought into production suggest that the system might cope with growing demand at least up until the late 2030s. Fossil fuel availability though indicates that prices will start accelerating well before then.
There is no alternative – nuclear energy is the only energy source that has any prospect of making good the looming fall in energy supply. Only nuclear power has any hope of being cheap enough to provide the energy to cook up the slew of chemicals and fuels we need to maintain our high standard of living. But it won’t be nuclear power as it is commonly understood. That is power plants burning U235 and using water as the coolant. Civilisation took a wrong turn way back in the 1950s when that technology became dominant in the nuclear power industry.
There are a number of reasons why it was a wrong turn. Firstly, U235 is only one thousandth of the nuclear fuel available to us. The best nuclear fuel, thorium, is eight hundred times more abundant. If you like to believe in a Creator who made the earth as a paradise for us to inhabit, U235 is the nuclear match made for us to light the fire that will sustain civilisation indefinitely. We are still burning that nuclear match though and we should have already moved on from that.
The second big problem with nuclear power plants running on U235 is decay heat. You can’t turn off nuclear power plants instantaneously. They continue to produce heat for a while after the reactions have been shut down. If the cooling water doesn’t circulate for some reason during this period, then there is a good chance you will get a hydrogen explosion. This is what happened at Fukushima which had three reactors blow up due to hydrogen explosions.
The question now being asked about thorium reactors is, if they are so wonderful, why haven’t they been developed yet? The only major company that once expressed an interest in developing molten salt thorium reactors was Teledyne Brown. There are a number of startups in the thorium space but none seem to have traction yet.
Perhaps the reason is that nobody has looked past the development of a commercial thorium reactor, a wonderful thing in itself, to the enormous commercial opportunity that follows from that. Let’s assume that each thorium power plant is 250 MWe, the same size as the conceptual design at Oak Ridge National Laboratory 50 years ago. Assuming no economic growth that required a higher rate of build, just replacing declining fossil fuel production to 2100 would require the building of 14,500 units at 250 MWe. The build rate would get to about 300 a year by mid-century. The rate could be 30% to 40% higher than that if carbon-based transport fuels are going to be created from hydrogen from electrolysis and carbon scavenged from forestry and agricultural waste. Also assuming that each unit lasts for sixty years before it has to be replaced, then the ramp up of replacement units in the second half of the century is just as fast as the initial ramp up as per Figure 3 following:
Figure 3: Number of 250 MWe nuclear reactors required by year to 2100
Thorium molten salt reactors, without the need for all the backup safety systems that U235 nuclear plants have, should be no more expensive to build than coal-fired plants. This is an overnight capital cost of $3,246/kW as opposed to U235 nuclear at $5,530/kW. At that rate, a 250 MWe plant would cost about $800 million. Building 300 per annum would provide a revenue of $240 billion per annum.
To put that in perspective, in the first quarter of 2015 the commercial division of Boeing sold 184 aircraft for $15.4 billion. That is an average revenue of $84 million per aircraft. The list price of a 737-800 is $93.3 million. Annualised, Boeing has a revenue of $60 billion per annum from its commercial aircraft division. Our prospective thorium reactor builder would become four times larger in the base case.
That will be the reward for saving humanity from a bleak future by developing the thorium molten salt reactor – owning an enormous industrial enterprise.
David Archibald, a visiting fellow at the Institute of World Politics in Washington, D.C., is the author of Twilight of Abundance (Regnery, 2014)
Meanwhile, the Russians have succeeded in developing a highly reliable liquid sodium cooled fast breeder reactor, the BN800, successor to the well established BN600:
http://atomicinsights.com/russia-continues-sustained-fast-breeder-reactor-effort/
Apparently they have succeeded where several other national programs failed, in getting liquid metal coolant to work reliably. They have also used liquid lead as a coolant.
This fourth generation fast breeder has potential to make a significant contribution to clean electricity generation for centuries to come, if political obstacles were to be overcome.
Considering that Chernobyl and F-shima were maintly a consequence of volatile coolant and inflammable fuel cladding, the idea of cooling with liquid sodium is horrific. I suspect the real reason the Dounreay fast breeder was shut down was the realisation that had a heat exchanger failed and molten sodium come into contact with water, they could have had an explostion which might have contaminated half of Scotland.
Liquid lead sounds more sensible.
Ian –
Oh, man, do I agree. Granted that liquid sodium’s capacity to cool is huge, but the level of disaster when someone f***s up royally will make Fukushima look like a firecracker. All it will take is water to come into contact with the sodium, and then maybe even Hiroshima will look small. But the AMOUNT of radioactive materials that might be released when the sodium goes BOOM will make entire regions of Russia uninhabitable for centuries.
NOT my first choice. Hell, liquid dynamite might be preferable to liquid sodium. Either way, with ONE screw up, write off areas way bigger than Scotland.
And wouldn’t the greens have a field day with THAT one? They would probably convince governments everywhere to go back to burning wood – and singing “Kumbaya”.
Ian
I worked at Dounreay for 6 months (on an MSc project working with their whole-body human alpha contamination monitor – a room shielded with old lead and steel to measure Pu and Am in workers’ lungs). About once every week there was a piercing sound heard across the whole site, the emergency venting of steam from the reactor. It was usually the same reason, liquid sodium leakage from the pipes at the location of welds.
It appears that the Soviets/Russians have simply done the obvious thing, found a way to make steel sodium containment without welds. The BN600 reactor at Obninsk has provided electricity to the grid stably for half a century, it is quoted as one of the most stable of ALL Russia’s nuclear reactors, conventional as well as fast-breeder. So the validity of saying that this “doesn’t work” ended before many of us were born. It does.
But I agree that liquid Pb does make sense also.
Liquid Pb is a horrible idea. You have to consider what happens to the activated coolant. Liquid sodium is better. Look at decay chains.
Looks like we don’t have to worry about running out of oil.
And if we do run low, we can always recycle our oil changes:
http://2.bp.blogspot.com/_orkXxp0bhEA/TDZzUV1oYMI/AAAAAAAAe1U/tueyRYprnBU/s1600/100708-refinery.jpg
I like your web site. I am definitely a skeptic BUT; next time you want to talk about nuclear issues consult someone who has a background in nuclear energy. Lots of errors. Thorium reactors have similar decay heat issues to U235 plants. They still need backup systems. Liquid salt systems have less but can also be done with U235. These are but a few of your misconceptions. My favorite plant ever was a U235 plant that was cooled by liquid sodium. In my opinion it was the safest design. Water cooled reactors aren’t synonymous with U235. The reason they went with water cooled is the Navy is heavily invested in nuclear power and molten salts are a rather poor idea in the ocean. Anyway, generally like your articles. This one is painfully wrong. Many gross conceptional errors concerning nuclear power.
Shane
Your post starts with
and ends with
Hmmm. I shall file your post under ‘Concern troll’ and I will ignore it.
Richard
That’s cool. I was a senior nuclear power plant operator and then head chemist. I am pro nuclear power. Also don’t buy into the global warming frenzy. Just pointing out a some faults in your description of Thorium reactors.
Shane
I made no “description of Thorium reactors”. In fact I made no mention of them.
Your reply to me is a red herring and a straw man wrapped up with an appeal to authority based on your anonymous claim to expertise. That is 4 logical fallacies in your post that consists of only 4 sentences.
In summation, your reply to my observation of your concern trolling is to demonstrate that you are a simple troll.
Richard
“Thorium molten salt reactors, without the need for all the backup safety systems that U235 nuclear plants have,”
Would be more accurate if you said “molten salt reactors, without the need for all the backup safety systems that pressurized water reactors have,” Thorium fuel and Uranium fuel have the same decay heat issues, the molten salt V.S. pressurized water reactor is the important issue. We have had several molten metal reactors, they just use U235 as fuel.
“The second big problem with nuclear power plants running on U235 is decay heat.”
Now I don’t know that you were implying that Thorium doesn’t have the same issue but it appears so. Again, totally down with using Thorium, but this issue is also true with Thorium.
I worked at the reactors that tested Thorium fuels, they’re fine. Any fuel source is a good one. You could use the plutonium out of old nuclear warheads instead of spiking them with highly radioactive material and burying them. It’s all good. One cool thing about Thorium is it can absorb a neutron followed by a beta decay to U233. You can collect the U233 and use it as fuel. This was all taken into account in the EBR II fuel cycle facility. It however was shutdown by the Clinton administration under Hazel O’leary and Bill Richardson.
Also there are several papers on scale, you would be better off cost wise to build a 750 MW plant(250 MW electrical) because of the savings of cost. This is actually a topic of debate among the nuclear operators. Rule of thumb is electrical is 1/3 of thermal power.
As far as the wrong turn in the fifties, Rickover was probably the most influential person in the development of the power plants. That is why we went with pressurized water reactors. Check out the EBR II reactor, it could be made with Thorium as well and is my personal favorite. Of course I was an operator there so I have a perference.
Also, check out the facebook page for navy nukes. Many of these people are current or former operators and this subject is hammered at least monthly. Go there and find some folks to chat with. They all love nuclear power and they will give you good feedback. I’m going to link your article there. They can be harsh but they mean well.
Shane
Your trolling has gone beyond being merely objectionable.
I said none of the things you quote me as having said.
In fact, I did not mention Thorium reactors. APOLOGISE!
Richard
Richard, quoting directly out of your article “Thorium molten salt reactors, without the need for all the backup safety systems that U235 nuclear plants have,” Really, you said that.
“The second big problem with nuclear power plants running on U235 is decay heat.” You also have this in your article as well.
How did you not say this? It is clearly in print.
Shane
I have NOT written an article on Thorium reactors in my life.
ALL YOUR SUPPOSED QUOTES OF ME ARE LIES.
Cite – preferably link to – where you claim I said these things.
Then, apologise for your despicable trolling and clear off.
Richard
Sorry, was commenting on the article by David Archibald. Don’t know why you replied at all. Not apologizing, but maybe that is why you seemed so clueless. Not sure why you commented on what I wrote. The quotes were from Archibald’s article. Why would you troll about comments you couldn’t even understand?