THE ENERGY CHALLENGE 2004 -- Nuclear
10.8.04   Murray Duffin, Retired

No aspect of the energy challenge is more polarized than that of nuclear energy. Both the pros and cons are very selective in presenting their arguments, and it is very difficult to get a balanced or objective view of the real trade-offs. While much of the opposition is emotional, deriving from fear of radiation, bombs, and Chernobyl, it is not unlikely that this polarization also arises from the fact that, at present, there may be as many real negatives as positives.

The Pros:
The main plusses presented in favor of nuclear are:

When these claims are examined in detail we find that:

A couple of the points are relatively true for us, because of the import share, i.e. we get to export much of the pollution, and the main suppliers, Canada and Australia, are secure allies.

The Cons
The major negatives presented by its opponents are:

A careful examination of these claims reveals that:

The Real Issues

On balance, probably the most telling issues are:

Resource depletion

Some people point out that there is not enough Uranium reasonably available in the earth’s crust to support much world growth in nuclear power, without facing another declining resource in a few decades. Again this is a false objection. There are 433 active reactors (excluding shipboard propulsion units) operating in the world today, with a combined capacity of about 350 GWe. They can generate about 10 quads of electricity per year. Argonne Labs estimates available Uranium as 3000 quads. If we tripled world nuclear capacity between now and 2030, (unlikely), and then ran flat, that would carry us to 2110. In addition we have 3 times as much thorium, which can be upgraded to fissile uranium in nuclear reactors, so even with major growth of present technology reactors we would be good for 2 centuries or so.

However present conventional reactors only consume about 1% of the fuel, or perhaps 2% after upgrading. The “Integral Fast Reactor” (IFR)4 would consume most of the fuel, and therefore stretch the available Uranium to 300,000 quads. Even with vastly expanded world consumption we have at least several centuries of fuel.

N. B. The IFR is also inherently safer in every respect than conventional reactors but IFR design was suspended in 1994 as a result of rather hysterical efforts by ill-informed anti-nuke activists who considered it to be a type of fast breeder reactor and open-ended source of near weapons grade plutonium. An even less informed House suspended development over the objections of a better-informed Senate.

Electricity Cost

Fully costed, nuclear generated electricity today costs from 6 to 10 cents/kWh, not competitive with coal or natural gas. However the main component of that cost is plant amortization at 5 to 7 cents/kWh. Most of our fleet of nuclear plants was built in the 1970s and is now approaching the end of the 30-year initial amortization period. About 7 plants have already been re-licensed for a longer useful life (now 50 years), and several more have applied for re-licensing. After amortization, the cost of electricity for these plants will drop to about 2 cents/kWh, a cost that makes electricity almost free, and that no other source of electricity can compete with. Experts feel that with sound maintenance, the lifetime of a nuclear plant can be near “forever”. Of course, this means that nuclear energy consumers, over the last 30 years have paid for very cheap energy for their progeny, an unusual and certainly unintentional act of altruism.

This point raises the question of cost for electricity from new nuclear plants. There are several ways of keeping such costs competitive. The first and most obvious is that operators of present plants will simply average their cost from new and fully amortized plants. Next, the high cost from numerous existing plants derived from huge cost overruns during construction, often due to regulatory delays. The initial cost of new plants can be expected to be lower, and indeed fully costed electricity from new plants is projected as <5 cents/kWh. If global warming is finally taken seriously in the USA (which now seems likely), and a carbon trading scheme is introduced, nuclear plants should be allowed to trade carbon credits, thus providing an income stream to offset amortization. Finally, if plant life is taken to be very long, as now seems certain, amortization can be spread over 50 or maybe even 100 years. With all of these possibilities, new nuclear power will certainly be competitive with fossil fuels even at today’s prices, and fossil fuel prices will only rise.

All of the above ignores the fact that nuclear R&D has been paid for by the taxpayer. R&D for e.g. gas turbines is paid for by the manufacturer and that cost is passed along in price to the customer. Historically, most of the nuclear R&D led to atom bombs and reactors for nuclear submarines so having the taxpayer pay was appropriate. That is no longer the case, but given the strength of the precedent nothing is likely to change. We can’t know the real cost of nuclear energy unless the industry pays its own R&D costs. We should consider such already “sunk” R&D cost as a gift to future generations, another little piece of altruism, that may offset some of the other problems we are leaving them.

No Nukes!

The anti-nuclear folk correctly point out that we can choose to phase out nuclear energy without any significant negative impact on our economy. We do not have a major American processing industry. The rest of the world will still provide a market for Australia and Canada. We will still be a small market for fuel for naval reactors and for medical and industrial isotopes. Since nuclear provides less than 3% of the energy we consume, since it does have some real drawbacks, and since there are better, lower cost alternatives, why bother with it? For sure it does not make sense to expand subsidization3 of a controversial energy source. With nuclear’s subsidies, wind/solar/hydrogen would be competitive, and is much more desirable.

Reality Check

That said, let’s consider reality. As natural gas and petroleum availability go into decline, and as the hydrogen economy develops, increasing electricity demand, nuclear will start to look more and more attractive. Resistance on the part of lawmakers is already dropping. The NEPDG, in their May 2001 report made this recommendation “In the context of developing advanced nuclear fuel cycles and next-generation technologies for nuclear energy, the United States should reexamine its policies, to allow for research, development and deployment of fuel conditioning methods (such as pyroprocessing) that reduce waste streams and enhance proliferation resistance.” They were referring to the IFR. In fact there is now a consortium of 10 countries, led by Argonne Labs of the USA, to define and develop the “fourth generation” nuclear reactor, dubbed the “Advanced Fast Reactor”, (AFR)6 a rebirth, with improvements of the IFR for which development was abandoned in 1994. It is expected that the first AFRs will go into service by 2030, and when petroleum does go into decline, that schedule is likely to be advanced. Argonne is also leading the Congressional Advanced Reactor Hydrogen Project, designing the Next Generation Nuclear Plant, and developing technology to prolong the working life of present reactors.

An alternative new reactor design, the helium cooled “pebble bed “ reactor (PBR)7 is also in development, with units expected to be in service in China8 and South Africa in the time frame of 2008 to 2012. Actually PBRs are not new. The first such reactor was operated in Germany for several years starting in the early 1980s. The PBR is claimed to be inherently fail-safe, in that overheating of the core forces passive shutdown, but there was a failure in the fuel feed to the German unit that resulted in the release of a plume of radioactive material, and led the German government to permanently shut the unit down. This specific failure mode could be prevented by design change. South Africa has plans to build at least 10 PBRs for domestic use, and to build up to 20 per year small modular “plug and play” units for export. China is targeting 300GWe of PBR capacity by 2050. South Korea is also in the planning stages of adding PBR capacity. Even Serbia has now announced plans to build a new reactor. Nuclear is at the beginning of a major comeback, especially in less developed countries (undoubtedly with USA involvement), but before long in the USA also, like it or not.

Sell the benefits.

What are the benefits and drawbacks of the new designs?
PBR: The major benefits claimed are:

The drawbacks are:

Only the inefficiency drawback is a problem in the USA.

AFRs: The major benefits claimed are:4

The drawbacks are:

Conclusions
Declining availability of natural gas and petroleum are going to shift a major portion of our energy burden to electricity. In response we will certainly turn to coal, renewables and nuclear. If the decline is sharp, which is very likely for natural gas, we will not be able to respond quickly enough on the supply side, especially given the very long permitting, building and commissioning times for nuclear (up to 10 years today). PBRs hold out promise to reduce this time to perhaps 2-3 years before 2010. When nuclear becomes again acceptable, we are likely to build PBRs for some years, while we accelerate development of AFRs. Before 2030 AFRs will almost undoubtedly be the reactor of choice. While nukes will always have inherent danger, AFRs have the promise of eliminating plutonium stockpiles, and can thus, on balance, make the world a safer place. There is still a need to overcome poorly informed and emotional resistance.

References:
1 http://www.newscientist.com/news/news.jsp?id=ns9999782
2 http://www.antenna.nl/wise/uranium/  for a lot of info the nuclear industry does not want to tell you.
3Jerry Taylor, the director of natural resource studies at the Cato Institute, a libertarian think tank, notes: “Were it nor for government subsidies, there wouldn’t be one nuclear power plant in this country.”
4 http://www.anlw.anl.gov/anlw_history/reactors/ifr.html
5 http://www.nationalcenter.org/NPA378.html
6 http://www.aps.org/units/fps/newsletters/2002/april/a1ap02.cfm
7 http://en.wikipedia.org/wiki/Pebble_bed_reactor
8 http://www.grist.org/news/daily/2004/09/03/china/index.html

 

 

Edward A. Reid, Jr.
10.8.04
Mr. Duffin,

Nicely done!

The "hydrogen economy" obviously will not be based on reforming natural gas. The identified alternative hydrogen sources are electrochemical and thermochemical production from water. This implies a major increase in electricity production and ultimately generating capacity. This new capacity will certainly not be natural gas-fueled. If climate change becomes a controlling issue, it won't be coal-fueled either unless permanent CO2 sequestration technology becomes economically available. That leaves nuclear and renewables. However, CO2 limitations would exclude biomass, so we're down to geothermal, solar and wind plus existing hydro. I can't wait to see the reaction to the proposal to install ~12 million large wind turbines nationwide.

It may actually be time for the US to get serious about the future energy supply. It would be a refreshing change!

 

Len Gould
10.8.04
Nice article. re. "There is still a need to overcome poorly informed and emotional resistance.", 2 points:

1) The only logical choice for at least the first 10 or so new (old-technology) units is to build the containment in a hardrock excavation 800 meters underground. Placing condensers and turbine at surface enables gravity to replace feedwater pumping, giving unlimited and totally reliable cooling. Also excavation is cheaper than present containments, and completely safe from eg. aircraft. Spent fuel permanently stored in adjacent excavation. If it tries to pull a TMI just pour the shaft full of borated concrete. With this technique I can't get the cost of a new e.g. CANDU (like Quinshan) above 3.3 cents / kWhr. v.s. clean coal at 5++? see http://www.ecologen.com

2) By what logic can anit-nukes oppose power reactors but say nothing about military nuclear-power fleets? In my estimation, to eliminate power nukes you'll enforce dependence for a long time on imported fossil fuels which can only be reliable with a powerful high-seas military.

Anyway, I've given up on logic and am developing novel solar / fuel powered generation which is going into prototype now. Actually by the math it'll generate cheaper than the above anyway. Who would have thought?

 

Len Gould
10.8.04
And before the windpower advocates get going I'd like to see them deal with this data http://www.vanderbilt.edu/radsafe/0405/msg00051.html. In summary, a large east-coast wind farm with 5 years operating record indicates reliability factor of 18%, with summer months often much worse.

 

Victor Bush
10.8.04
Murray –

Very well researched articles written for the layman. The four articles you have submitted to this forum so far come at a time when we, as a nation, need to look very closely at the role energy costs play in our economic well being.

Your articles should be required reading in Political Science 101.

 

Michael McCarthy
10.8.04
Dr. Claudio Filippone, director of the Center for Advanced Energy Concepts, a branch of the U-Md Aerospace Engineering Dept., claims to have developed an "active neutronic moderator" capable of fine-tuning a nuclear reaction using simple films of steam. He explains, “This is the heart of CAESAR (Clean and Environmentally Safe Advanced Reactor). With it, thermodynamic efficiency has been enhanced due to a dramatically increased heat transfer coefficient. Cooling of the fuel is achieved and enhanced by films of steam. And because water has been thinned into steam, even not-so-energetic delayed neutrons can now travel between different rods, causing fission." Nuclear fuel stays in a conventional nuclear reactor for 2 – 3 years, after which the U-235 is depleted and delayed neutrons have insufficient energy to pass through the water. Then it is known as spent fuel and becomes nuclear waste. “But CAESAR can use spent fuel,” continues Dr. Filippone, “so no one should need weapons-grade uranium any more. What’s more, we can go back to the environment and say ‘We dumped this stockpile of spent fuel here. We’re taking it back because we can get electricity out of it for several centuries.’” Go to http://www.caesar.umd.edu/ for more.

 

Rodney Adams
10.8.04
Murray:

I just read your Energy Challenge - Nuclear piece. Although you make some reasonable points, you have quite a few of your facts confused. Here are a few examples: The first German pebble bed reactor, the AVR (Arbeitsgemeinschaft Versuchsreaktor) began operating on August 26, 1966, not the 1980s. It was decomissioned in 1988 after more than 20 years of experimentation and operation. Nuclear O&M (which even includes fuel storage and decommissioning allowances) range as low as 1.13 cents per kilowatt hour (Duke Power's Catawba) and the average in 2003 was 1.72 cents per kilowatt hour (Nucleonics Week Sep 2004) which is below the range that you quoted. Gas turbine R&D is and has always been largely funded by governments in the form of development programs for jet engines for combat aircraft and gas turbine engines for ships. In addition, there a plenty of DoE subsidies for development of advanced power production gas turbines. I would be very interested in seeing a calculation with stated assumptions that supports your contention that thin film solar has a higher energy density than uranium. I would also be interested in just which fossil fuel technologies are "totally fail safe". The last time I checked, all of the involved fuels (coal, oil and gas) are flammable and all have been responsible for deaths within the past few months. Oil and gas have definitely been involved in more terrorists attacks, some of which resulted in pretty spectacular events - like enormous sky scrapers collapsing on themselves. I think I will save my other comments for a rebuttal article. Rod Adams

www.atomicinsights.com

 

Jack Ellis
10.11.04
I generally agree with your conclusion that nuclear power is an option worth developing. However it's going to be a tough sell unless thought leaders, government and industry can convince the voters that it's safe enough. Most people don't understand the technical details and they don't want to understand them, either. Images of disaster at Chernobyl and the accident at Three Mile Island are still fresh in the public's mind and anti-nuclear activists will exploit those images for maximum effect. Effective rebuttals of the disaster scenarios begins with substantial agreement among industry and government that new nuclear development is in the national interest, followed by an extensive public education campaign that carefully dismantles the scare tactics environmental lobbyists will undoubtedly use.

I don't believe for one minute that nuclear power is our energy savior. It needs to be part of a menu of options that helps insulate us from the adverse consequences of technical failures (TMI, inability to vitrify wastes), unrealistic projections for construction and operating costs (electricity too cheap to meter) and lack of political will. In short, we should never put all of our energy eggs in a single basket.

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