Advanced High Temperature Reactor: Lower Costs, Enable Deep Burn and Advanced Fuel Cycle Reactors

http://en.wikipedia.org/wiki/Mean_lifetime

If the decaying quantity is the same as the number of discrete elements of a set, it is possible to compute the average length of time for which an element remains in the set. This is called the mean lifetime (or simply the lifetime) and it can be shown that it relates to the decay rate,

tau = 1 / lambda.

<snip>

Therefore, the mean lifetime tau is equal to the half-life divided by the natural log of 2, or:

tau = t / ln 2 = 1.442695040888963 t.

E.g. Polonium-210 has a half-life of 138 days, and a mean lifetime of 200 days.

http://www.wolframalpha.com/input/?i=cesium+137

cesium 137

Decay properties:

half-life | 30.08 years
lifetime | 43.38 years
...

http://www.cnn.com/TECH/space/9909/30/mars.metric.02/

Metric mishap caused loss of NASA orbiter
September 30, 1999

(CNN) -- NASA lost a $125 million Mars orbiter because a Lockheed Martin engineering team used English units of measurement while the agency's team used the more conventional metric system for a key spacecraft operation, according to a review finding released Thursday.

<snip>

Pebble-bed nuclear reactor gets pulled

South Africa cuts funding for energy technology project.
Linda Nordling

Hopes for the development of pebble-bed nuclear reactor technology, long held up as a safer alternative to conventional nuclear power, have suffered a blow. Last week, the South African government confirmed that it will effectively stop funding a long-term project to develop the technology.

The development company, Pebble Bed Modular Reactor (PBMR), based near Pretoria, says that it is now considering axing three-quarters of its 800 staff, about half of whom are scientists or engineers. "The resources available to the company will not sustain the current cost structure," the company says. The cuts could trigger an exodus of nuclear expertise from South Africa, although some argue that government funding has kept the project going for too long in the face of growing problems.

South Africa started to develop its pebble-bed reactor design in the mid-1990s, hoping that it would deliver cheap electricity and open up a lucrative export industry. It licensed the technology from Germany's Jülich Research Centre, which abandoned a working prototype reactor in 1991 after citing poor business opportunities.

Eskom, South Africa's main electricity generator, based in Johannesburg, set up the PBMR in 1999 to develop the technology into a economically viable reactor. "It caught the mood in South Africa, and the feeling among South Africans was that their technology was as good as anybody's," says Steve Thomas, an energy-policy researcher at the University of Greenwich, London. "This was their chance to show the world what they could do."

The proposed reactor would have used...

Public discussions of nuclear power, and a surprising number of articles in peer-reviewed journals, are increasingly based on four notions unfounded in fact or logic: that

1. variable renewable sources of electricity (windpower and photovoltaics) can provide little or no reliable electricity because they are not “baseload”—able to run all the time;
2. those renewable sources require such enormous amounts of land, hundreds of times more than nuclear power does, that they’re environmentally unacceptable;
3. all options, including nuclear power, are needed to combat climate change; and
4. nuclear power’s economics matter little because governments must use it anyway to protect the climate.

For specificity, this review of these four notions focuses on the nuclear chapter of Stewart Brand’s 2009 book Whole Earth Discipline, which encapsulates similar views widely expressed and cross-cited by organizations and individuals advocating expansion of nuclear power. It’s therefore timely to subject them to closer scrutiny than they have received in most public media.

This review relies chiefly on five papers, which I gave Brand over the past few years but on which he has been unwilling to engage in substantive discussion. They document6 why expanding nuclear power is uneconomic, is unnecessary, is not undergoing the claimed renaissance in the global marketplace (because it fails the basic test of cost-effectiveness ever more robustly), and, most importantly, will reduce and retard climate protection. That’s because—the empirical cost and installation data show—new nuclear power is so costly and slow that, based on empirical U.S. market data, it will save about 2–20 times less carbon per dollar, and about 20–40 times less carbon per year, than investing instead in the market winners—efficient use of electricity and what The Economist calls “micropower,”...


The “baseload” myth

Brand rejects the most important and successful renewable sources of electricity for one key reason stated on p. 80 and p. 101. On p. 80, he quotes novelist and author Gwyneth Cravens’s definition of “baseload” power as “the minimum amount of proven, consistent, around-the-clock, rain-or-shine power that utilities must supply to meet the demands of their millions of customers.”21 (Thus it describes a pattern of aggregated customer demand.) Two sentences later, he asserts: “So far comes from only three sources: fossil fuels, hydro, and nuclear.” Two paragraphs later, he explains this dramatic leap from a description of demand to a restriction of supply: “Wind and solar, desirable as they are, aren’t part of baseload because they are intermittent—productive only when the wind blows or the sun shines. If some sort of massive energy storage is devised, then they can participate in baseload; without it, they remain supplemental, usually to gas-fired plants.”

That widely heard claim is fallacious. The manifest need for some amount of steady, reliable power is met by generating plants collectively, not individually. That is, reliability is a statistical attribute of all the plants on the grid combined. If steady 24/7 operation or operation at any desired moment were instead a required capability of each individual power plant, then the grid couldn’t meet modern needs, because no kind of power plant is perfectly reliable. For example, in the U.S. during 2003–07, coal capacity was shut down an average of 12.3% of the time (4.2% without warning); nuclear, 10.6% (2.5%); gas-fired, 11.8% (2.8%). Worldwide through 2008, nuclear units were unexpectedly unable to produce 6.4% of their energy output.26 This inherent intermittency of nuclear and fossil-fueled power plants requires many different plants to back each other up through the grid. This has been utility operators’ strategy for reliable supply throughout the industry’s history. Every utility operator knows that power plants provide energy to the grid, which serves load. The simplistic mental model of one plant serving one load is valid only on a very small desert island. The standard remedy for failed plants is other interconnected plants that are working—not “some sort of massive energy storage devised.”

Modern solar and wind power are more technically reliable than coal and nuclear plants; their technical failure rates are typically around 1–2%. However, they are also variable resources because their output depends on local weather, forecastable days in advance with fair accuracy and an hour ahead with impressive precision. But their inherent variability can be managed by proper resource choice, siting, and operation. Weather affects different renewable resources differently; for example, storms are good for small hydro and often for windpower, while flat calm weather is bad for them but good for solar power. Weather is also different in different places: across a few hundred miles, windpower is scarcely correlated, so weather risks can be diversified. A Stanford study found that properly interconnecting at least ten windfarms can enable an average of one-third of their output to provide firm baseload power. Similarly, within each of the three power pools from Texas to the Canadian border, combining uncorrelated windfarm sites can reduce required wind capacity by more than half for the same firm output, thereby yielding fewer needed turbines, far fewer zero-output hours, and easier integration.

A broader assessment of reliability tends not to favor nuclear power. Of all 132 U.S. nuclear plants built—just over half of the 253 originally ordered—21% were permanently and prematurely closed due to reliability or cost problems. Another 27% have completely failed for a year or more at least once. The surviving U.S. nuclear plants have lately averaged ~90% of their full-load full-time potential—a major improvement31 for which the industry deserves much credit—but they are still not fully dependable. Even reliably-running nuclear plants must shut down, on average, for ~39 days every ~17 months for refueling and maintenance. Unexpected failures occur too, shutting down upwards of a billion watts in milliseconds, often for weeks to months. Solar cells and windpower don’t fail so ungracefully.

Power plants can fail for reasons other than mechanical breakdown, and those reasons can affect many plants at once. As France and Japan have learned to their cost, heavily nuclear-dependent regions are particularly at risk because drought, earthquake, a serious safety problem, or a terrorist incident could close many plants simultaneously. And nuclear power plants have a unique further disadvantage: for neutron-physics reasons, they can’t quickly restart after an emergency shutdown, such as occurs automatically in a grid power failure...

April 22, 2009 NYTimes
Energy Regulatory Chief Says New Coal, Nuclear Plants May Be Unnecessary
By NOELLE STRAUB AND PETER BEHR, Greenwire

No new nuclear or coal plants may ever be needed in the United States, the chairman of the Federal Energy Regulatory
Commission said today.
"We may not need any, ever," Jon Wellinghoff told reporters at a U.S. Energy Association forum...

Landmark report explodes renewable energy myths

Comprehensive study concludes 100 per cent renewable energy supplies are technically feasible and economically attractive
Europe can switch to low carbon sources of energy without jeopardising reliability or forcing up energy bills to punitive levels, according to a major new study that claims to be the most comprehensive assessment to date of the viability of zero carbon power supplies.

Roadmap 2050: a practical guide to a prosperous, low-carbon Europe will be released later today and will demonstrate how transitioning to a low or zero carbon power supply based on high levels of renewable energy would have no impact on reliability, and would have little impact on the cost of producing electricity in the period up to 2050.

The report was developed by think tank the European Climate Foundation (ECF) in collaboration with a number of leading economists and energy industry experts, and includes contributions from McKinsey, KEMA, Imperial College London and Oxford Economics.

Its analysis argues that cost effective zero carbon power is not reliant on technology breakthroughs, although it warns that they would help to further reduce the cost of decarbonisation.

Matt Phillips, a senior associate with the ECF, said many of assumptions made at the outset of the research project had been proved wrong....

Public discussions of nuclear power, and a surprising number of articles in peer-reviewed journals, are increasingly based on four notions unfounded in fact or logic: that

1. variable renewable sources of electricity (windpower and photovoltaics) can provide little or no reliable electricity because they are not “baseload”—able to run all the time;
2. those renewable sources require such enormous amounts of land, hundreds of times more than nuclear power does, that they’re environmentally unacceptable;
3. all options, including nuclear power, are needed to combat climate change; and
4. nuclear power’s economics matter little because governments must use it anyway to protect the climate.

For specificity, this review of these four notions focuses on the nuclear chapter of Stewart Brand’s 2009 book Whole Earth Discipline, which encapsulates similar views widely expressed and cross-cited by organizations and individuals advocating expansion of nuclear power. It’s therefore timely to subject them to closer scrutiny than they have received in most public media.

This review relies chiefly on five papers, which I gave Brand over the past few years but on which he has been unwilling to engage in substantive discussion. They document6 why expanding nuclear power is uneconomic, is unnecessary, is not undergoing the claimed renaissance in the global marketplace (because it fails the basic test of cost-effectiveness ever more robustly), and, most importantly, will reduce and retard climate protection. That’s because—the empirical cost and installation data show—new nuclear power is so costly and slow that, based on empirical U.S. market data, it will save about 2–20 times less carbon per dollar, and about 20–40 times less carbon per year, than investing instead in the market winners—efficient use of electricity and what The Economist calls “micropower,”...


The “baseload” myth

Brand rejects the most important and successful renewable sources of electricity for one key reason stated on p. 80 and p. 101. On p. 80, he quotes novelist and author Gwyneth Cravens’s definition of “baseload” power as “the minimum amount of proven, consistent, around-the-clock, rain-or-shine power that utilities must supply to meet the demands of their millions of customers.”21 (Thus it describes a pattern of aggregated customer demand.) Two sentences later, he asserts: “So far comes from only three sources: fossil fuels, hydro, and nuclear.” Two paragraphs later, he explains this dramatic leap from a description of demand to a restriction of supply: “Wind and solar, desirable as they are, aren’t part of baseload because they are intermittent—productive only when the wind blows or the sun shines. If some sort of massive energy storage is devised, then they can participate in baseload; without it, they remain supplemental, usually to gas-fired plants.”

That widely heard claim is fallacious. The manifest need for some amount of steady, reliable power is met by generating plants collectively, not individually. That is, reliability is a statistical attribute of all the plants on the grid combined. If steady 24/7 operation or operation at any desired moment were instead a required capability of each individual power plant, then the grid couldn’t meet modern needs, because no kind of power plant is perfectly reliable. For example, in the U.S. during 2003–07, coal capacity was shut down an average of 12.3% of the time (4.2% without warning); nuclear, 10.6% (2.5%); gas-fired, 11.8% (2.8%). Worldwide through 2008, nuclear units were unexpectedly unable to produce 6.4% of their energy output.26 This inherent intermittency of nuclear and fossil-fueled power plants requires many different plants to back each other up through the grid. This has been utility operators’ strategy for reliable supply throughout the industry’s history. Every utility operator knows that power plants provide energy to the grid, which serves load. The simplistic mental model of one plant serving one load is valid only on a very small desert island. The standard remedy for failed plants is other interconnected plants that are working—not “some sort of massive energy storage devised.”

Modern solar and wind power are more technically reliable than coal and nuclear plants; their technical failure rates are typically around 1–2%. However, they are also variable resources because their output depends on local weather, forecastable days in advance with fair accuracy and an hour ahead with impressive precision. But their inherent variability can be managed by proper resource choice, siting, and operation. Weather affects different renewable resources differently; for example, storms are good for small hydro and often for windpower, while flat calm weather is bad for them but good for solar power. Weather is also different in different places: across a few hundred miles, windpower is scarcely correlated, so weather risks can be diversified. A Stanford study found that properly interconnecting at least ten windfarms can enable an average of one-third of their output to provide firm baseload power. Similarly, within each of the three power pools from Texas to the Canadian border, combining uncorrelated windfarm sites can reduce required wind capacity by more than half for the same firm output, thereby yielding fewer needed turbines, far fewer zero-output hours, and easier integration.

A broader assessment of reliability tends not to favor nuclear power. Of all 132 U.S. nuclear plants built—just over half of the 253 originally ordered—21% were permanently and prematurely closed due to reliability or cost problems. Another 27% have completely failed for a year or more at least once. The surviving U.S. nuclear plants have lately averaged ~90% of their full-load full-time potential—a major improvement31 for which the industry deserves much credit—but they are still not fully dependable. Even reliably-running nuclear plants must shut down, on average, for ~39 days every ~17 months for refueling and maintenance. Unexpected failures occur too, shutting down upwards of a billion watts in milliseconds, often for weeks to months. Solar cells and windpower don’t fail so ungracefully.

Power plants can fail for reasons other than mechanical breakdown, and those reasons can affect many plants at once. As France and Japan have learned to their cost, heavily nuclear-dependent regions are particularly at risk because drought, earthquake, a serious safety problem, or a terrorist incident could close many plants simultaneously. And nuclear power plants have a unique further disadvantage: for neutron-physics reasons, they can’t quickly restart after an emergency shutdown, such as occurs automatically in a grid power failure...

Amory Lovins, a MacArthur Fellow and consultant physicist, is among the world’s leading innovators in energy and its links with resources, security, development and the environment. He has advised energy and many other industries for more than three decades, as well as the U.S. Departments of Energy and Defense. A former Oxford don, Amory Lovins advises major firms and governments worldwide and has briefed 19 heads of state.

Lovins’ work focuses on transforming hydrocarbon, automobile, real estate, electricity, water, semiconductor, and several other sectors toward advanced resource productivity. Amory Lovins co-founded and is Chairman and Chief Scientist of Rocky Mountain Institute, an independent, market-oriented, entrepreneurial, nonprofit, nonpartisan think-and-do tank, that creates abundance by design. RMI has served or been invited by more than 80 Fortune 500 firms, redesigning more than $30 billion worth of facilities in 29 sectors, with much of its path-finding work involving advanced resource productivity (typically with expanding returns to investment) and innovative business strategies.

Amory has held several visiting academic chairs, most recently as MAP/Ming Professor in Stanford’s School of Engineering, offering the university’s first course on advanced energy efficiency. He has also authored or co-authored hundreds of papers and twenty-nine books including: Small Is Profitable: The Hidden Economic Benefits of Making Electrical Resources the Right Size - an Economist “book of the year” blending financial economics with electrical engineering, and the Pentagon co-sponsored Winning the Oil Endgame, a roadmap for eliminating U.S. oil use by the 2040s, led by business for profit.

His work in over 50 countries has been recognized by the “Alternative Nobel,” Blue Planet, Volvo, Onassis, Nissan, Shingo, Goff Smith, and Mitchell Prizes, the Benjamin Franklin and Happold Medals, ten honorary doctorates, honorary membership of the American Institute of Architects, Foreign Membership of the Royal Swedish Academy of Engineering Sciences, honorary Senior Fellowship of the Design Futures Council, and the Heinz, Lindbergh, Jean Meyer, Time Hero for the Planet, Time International Hero of the Environment, Popular Mechanics Breakthrough Leadership, and World Technology Awards.

The Wall Street Journal named Amory Lovins one of thirty-nine people worldwide "most likely to change the course of business.” Newsweek has praised him as "one of the Western world's most influential energy thinkers" and Car magazine ranked him the “twenty-second most powerful person in the global automotive industry.”

http://www.nirs.org/factsheets/pbmrfactsheet.htm

<snip>

"INHERENTLY SAFE" GERMAN PBMR COVERS UP RADIATION ACCIDENT AND SHUTS DOWN

As Dr. Edward Teller, the father of the H-bomb said, "Sooner or later a fool will prove greater than the proof even in a foolproof system." Accidents can and do happen in the inherently dangerous business of splitting the atom. Human error occurs at every level of development, construction and operation of the process. Material and component failures along with aging can break down or defeat operational and safety systems.

In 1985, the experimental THTR-300 PBMR on the Ruhr in Hamm-Uentrop, Germany was also offered as accident proof--with the same promise of an indestructible carbon fuel cladding capable of retaining all generated radioactivity. Following the April 26, 1986 Chernobyl nuclear reactor accident and graphite fire in Ukraine, the West German government revealed that on May 4, the 300-megawatt PBMR at Hamm released radiation after one of its spherical fuel pebbles became lodged in the pipe feeding the fuel to the reactor. Operator actions during the event caused damage to the fuel cladding.

Radioactivity was released with the escaping helium and radioactive fallout was deposited as far as two kilometers from the reactor. The fallout in the region was high enough to initially be blamed on Chernobyl. Government officials were then alerted by scientists in Freiburg who reported that as much as 70 % of the region’s contamination was not of the type of radiation leaking hundreds of miles away in Ukraine. Dismayed by an attempt to conceal the reactor malfunction and confronted with mounting public pressure in light of the Chernobyl accident only days prior, the state ordered the reactor to close pending a design review.

Continuing technical problems including a lack of quality control resulting in damage to unused fuel pebbles and radiation-induced bolt head failures in the reactor’s gas channels resulted in the unit’s closure in late 1988. Citing doubts about reliability, the government refused to further subsidize utility funding and instead approved plans for decommissioning the reactor.

<snip>

Fresh fuel going INTO the reactor is no more
radioactive than when it was dug out of the
ground.
...
When will people stop falling for such deceptions?

http://www.pbmr.co.za/index.asp?Content=224

<snip>

The uranium-235 isotope occurs in natural uranium at a concentration of approximately 0.7 percent. In order to have a self-sustaining or "chain" reaction, the uranium in the PBMR fuel is enriched to about 9.6 percent in uranium-235, which is the isotope of uranium which mainly undergoes fission in the core.

The reactor is continuously replenished with fresh or re-usable fuel from the top, while used fuel is removed from the bottom. After each pass through the reactor core, the fuel pebbles are measured to determine the amount of fissionable material left. If a pebble still contains a usable amount of the fissile material, it is returned to the reactor at the top for a further cycle. Each cycle takes just over three months.

Each pebble passes through the reactor about ten times and lasts about 1000 days before it is spent, which means that a reactor will used 13 total fuel loads in its design lifetime of 40 years.

<snip>

http://www.thebulletin.org/web-edition/features/the-demise-of-the-pebble-bed-modular-reactor

The demise of the pebble bed modular reactor
By Steve Thomas | 22 June 2009

Article Highlights
* After years of investment, South Africa has abandoned its plan to develop a fleet of electricity-generating pebble bed modular reactors (PBMR), once hyped as the future of nuclear power.
* Problems with the PBMR aren't new; a 2008 German report chronicles Germany's own problems developing the reactor since 1967.
* China, still developing PBMR-based power reactor designs, has taken a slow approach and it is unclear if they have run into problems as well.

In February, Pebble Bed Modular Reactor (PBMR) Ltd., an eponymously named South African company announced a major change of strategy. After 10 years of development it said it was abandoning plans to build a full-size 165-megawatt-electric demonstration plant. Furthermore, PBMR Ltd. said it will try to redirect its future plans for the reactor from electricity generation toward thermal applications, such as coal gasification and water desalination. With government funding set to run out next year, the company will have to close if new funding is not found.

<snip>

The technological root of both the South African and the Chinese PBMRs is the German high-temperature, gas-cooled reactor (HTGR) developed at the government's Jülich research center outside Cologne. A German company promoted the pebble bed design for a couple of years with high expectations that Russia would buy the technology. These hopes never materialized, however, and in 1991, it abandoned the reactor design citing a lack of realistic business prospects. It did, however, continue selling technology licenses, most notably to companies in South Africa and China.

In 1993, the South African utility Eskom took up a PBMR design that, unlike its predecessors, was expected to generate electricity using a gas turbine driven directly by its helium coolant. In 1999, Eskom set up PBMR Ltd. to develop and market the PBMR and to complete a feasibility study. The subsidiary raised money, but several investors eventually pulled out of the project. The end of the feasibility phase of the project was never announced publicly, although it appears to have been completed in March 2004.

<snip>

The Jülich report further recommends that gas-tight containment structures be built for any commercial pebble bed plant deployed and that further research and development is necessary to evaluate the safety of the design and to understand why such high temperatures were experienced at the AVR. The need for such containments for PBMR-based plants has been the subject of disagreement for some time. PBMR Ltd. has claimed the pebble bed is "intrinsically safe" and "melt-down proof" and has argued that no pressure containment is needed and that the emergency evacuation zone needs to be no larger than the plant site itself. If a containment structure is required, the additional cost would make the reactor prohibitively expensive to build commercially. Although the Jülich report is bitterly contested by PBMR advocates, the high credibility of Jülich, which submitted the report to an extensive peer-review process, means it cannot simply be dismissed.

<snip>

http://www.democraticunderground.com/discuss/duboard.php?az=view_all&address=115x188383

Pebble bed reactor too expensive for electricity
so they're going to redesign it for melting oil from tar sands.

http://www.theclimategroup.org/our-news/interviews/2004/10/15/stephen-pacala/

In the August 2004 issue of Science, Stephen Pacala and Robert Socolow of Princeton's Carbon Mitigation Initiative published a paper identifying 15 existing technologies that could each prevent 1 billion tons a year worth of carbon emissions by 2054. Pacala and Socolow have created a graph that divides the problem into the seven 1 billion-ton-per-year "wedges" which are required to halt the rise in greenhouse gas emissions, and stabilize the concentration of carbon dioxide in the atmosphere at 500 parts per million (ppm) (see figures below).

Their findings provide a strong counter to the argument that major new technologies need to be developed before significant mitigation of emissions can begin.

<snip>

Q. What wedges are the least worth pursuing, and would it be the ones with the shortest lifetimes, ie. the forestry and agriculture projects?

A. I actually think those are among the ones that are the most worth pursuing. Right now I see one titanic obstacle to climate change mitigation, and that is the United States (US) government. If the US government were leading the charge, then everyone else would be in its slipstream and we would have this problem solved. In the US, the agricultural sector is incredibly powerful. On the issue of climate change, farm state senators need to see something that will be of value to their constituents, and that is where agricultural soils really come to the fore. If we can convince a few representatives from a few states that this is in the interest of their constituents, it could help tip the debate in the US.

I personally think nuclear is a non-starter. In the article we were not trying to choose sides, only to point out the mitigation technologies that are already in place. However, I cannot imagine that in this era of concerns about terrorism that we are going to start the production of fissionable material all over the world. It is disingenuous when the Bush administration says that the way to solve this problem is through coal and nuclear. Clean coal through carbon capture is fine if it can be made to work. But if you actually injected all of the CO2 produced in the United States (1.5 billion tonnes) the entire country would jack up in the air by 1mm/year. You don't have to be a scientist to know that is not sustainable. If you try to solve even one wedge of this problem with nuclear, it would require a doubling in the amount of nuclear power deployed. Solving the problem entirely with nuclear means increasing deployment by a factor of 10, and if you calculate how many of these plants would have to be in countries like Sudan and Afghanistan, you are just not going to do it.

<snip>

http://www.ucsusa.org/nuclear_power/nuclear_power_and_global_warming/nuclear-power-resurgence.html

Nuclear Power: A Resurgence We Can't Afford

<snip>

The economics of nuclear power alone could be the most difficult hurdle to surmount. A new UCS analysis, Climate 2030: A National Blueprint for a Clean Energy Economy, finds that the United States does not need to significantly expand its reliance on nuclear power to make dramatic cuts in power plant carbon emissions through 2030—and indeed that new nuclear reactors would largely be uneconomical.

That analysis shows that by significantly expanding the use of energy efficiency and low-cost and declining-cost renewable energy sources, consumers and businesses could reduce carbon emissions from power plants as much as 84 percent by 2030 while saving $1.6 trillion on their energy bills. And, under the Blueprint scenario, because of their high cost, the nation would not build more than four new nuclear reactors already spurred by existing loan guarantees from the Department of Energy (DOE) and other incentives.

A forced nuclear resurgence, in contrast, could make efforts to cut the nation’s global warming emissions much more costly, given the rising projected costs of new nuclear reactors. A nuclear power resurgence that relies on new federal loan guarantees would also risk repeating costly bailouts of the industry financed by taxpayers and ratepayers twice before.

http://www.democraticunderground.com/discuss/duboard.php?az=view_all&address=115x191961

<snip>

Note to all: Do I want to build all those nuclear plants. No. Do I think we could do it without all those nuclear plants. Definitely. Therefore, should I be quoted as saying we “must” build all those nuclear plants, as the Drudge Report has, or even that I propose building all those plants? No. Do I think we will have to swallow a bunch of nuclear plants as part of the grand bargain to make this all possible and that other countries will build most of these? I have no doubt. So it stays in “the solution” for now.

<snip>

From the first fixed price turnkey reactors in the 1960s to the May 2009 cost projection of the Massachusetts Institute of Technology, the claim that nuclear power is or could be cost competitive with alternative technologies for generating electricity has been based on hope and hype. In the 1960s and 1970s, the hope and hype analyses prepared by reactor vendors and parroted by government officials helped to create what came to be known as the “great bandwagon market.” In about a decade utilities ordered over 200 nuclear reactors of increasing size.

Unfortunately, reality did not deliver on the hope and the hype. Half of the reactors ordered in the 1960s and 1970s were cancelled, with abandoned costs in the tens of billions of dollars. Those reactors that were completed suffered dramatic cost overruns (see Figure ES-1). On average, the final cohort of great bandwagon market reactors cost seven times as much as the cost projection for the first reactor of the great bandwagon market. The great bandwagon market ended in fierce debates in the press and regulatory proceedings throughout the 1980s and 1990s over how such a huge mistake could have been made and who should pay for it.

In an eerie parallel to the great bandwagon market, a series of startlingly low-cost estimates prepared between 2001 and 2004 by vendors and academics and supported by government officials helped to create what has come to be known as the “nuclear renaissance.” However, reflecting the poor track record of the nuclear industry in the U.S., the debate over the economics of the nuclear renaissance is being carried out before substantial sums of money are spent. Unlike the 1960s and 1970s, when the utility industry, reactor vendors and government officials monopolized the preparation of cost analyses, today Wall Street and independent energy analysts have come forward with much higher estimates of the cost of nuclear reactors.

The most recent cost projections are, on average, over four times as high as the initial nuclear renaissance projections.

Even though the early estimates have been subsequently revised upward in the past year and utilities offered some estimates in regulatory proceedings that were twice as high as the initial projections, these estimates remain well below the projections from Wall Street and independent analysts. Moreover, in an ominous repeat of history, utilities are insisting on cost-plus treatment of their reactor projects and have steadfastly refused to shoulder the responsibility for cost overruns.

One thing that utilities and Wall Street analysts agree on is that nuclear reactors will not be built without massive direct subsidies either from the federal government or ratepayers, or from both.

In this sense, nuclear reactors remain as uneconomic today as they were in the 1980s when so many were cancelled or abandoned.

http://www.democraticunderground.com/discuss/duboard.php?az=show_mesg&forum=115&topic_id=191961&mesg_id=191965

NYC_SKP DU Moderator Donating Member (1000+ posts) Journal Click to send private message to this author Click to view this author's profile Click to add this author to your buddy list Click to add this author to your Ignore list Tue Mar-31-09 11:37 AM
Response to Original message
1. The Princeton Wedge Stabilization Game.

The Princeton Wedge Stabilization Game is pretty fun.
http://www.princeton.edu/wedges /
We played this at an IPCC conference in SF in 2007.

<snip>

http://krugman.blogs.nytimes.com/2009/10/16/a-counterintuitive-train-wreck/

October 16, 2009, 10:10 am
A counterintuitive train wreck

Uh oh. I trust Joe Romm on climate — and his verdict on Superfreakonomics is pretty damning. I’ll get to work on the book myself, but it doesn’t look good.

<snip>

http://en.wikipedia.org/wiki/Joseph_J._Romm

Joseph J. Romm (born June 27, 1960) is an American author, blogger, physicist<1> and climate expert<2> who concentrates on methods of reducing greenhouse gas emissions and global warming and increasing energy security through energy efficiency, green energy technologies and green transportation technologies.<3><4> In December 2008, Romm was elected a Fellow of the American Association for the Advancement of Science. In March 2009, Rolling Stone magazine named Romm to its list of "100 People Who Are Changing America".<5> In September 2009, Time magazine named him one of its "Heroes of the Environment (2009)", calling him "The Web's most influential climate-change blogger".<6>

Romm is a Senior Fellow at the Center for American Progress, where he writes and maintains their climate blog, ClimateProgress.org. In 2008, Time magazine named Romm's blog one of the "Top 15 Green Websites",<7> and in 2010, Time included Romm's blog in a list of the 25 "Best Blogs of 2010"<8> Romm is also the executive director and founder of the non-profit Center for Energy and Climate Solutions, which helps businesses and U.S. States adopt high-leverage strategies for saving energy and cutting pollution and greenhouse gas emissions<4> and is a principal of the Capital E Group, an energy technology consultant. Romm also writes regularly for several energy and news websites.

In the 1990s, Romm served as Acting Assistant Secretary of the U.S. Department of Energy. Romm has published several books on global warming and energy technology. Technology Review wrote that his December 2006 book, Hell and High Water, "provides an accurate summary of what is known about global warming and climate change, a sensible agenda for technology and policy, and a primer on how political disinformation has undermined climate science."<9> Romm's 2010 book, Straight Up, released in April 2010, is "largely a selection of his best blog postings over the past few years related to climate change issues".<10>

<snip>

Romm graduated from Middletown High School in 1978. He then attended the Massachusetts Institute of Technology, where he earned a Bachelor of Science degree in 1982 and a Ph.D. in 1987, both in physics.<13> He pursued part of his graduate work at the Scripps Institution of Oceanography.<14> In 1987, Romm was awarded an American Physical Society Congressional Science Fellowship for the U.S. House of Representatives, where he provided science and security policy advice on the staff of Representative Charles E. Bennett.<15>

<snip>

http://twitter.com/algore/statuses/12469954346

Joe Romm has an important new book out. I recommend it: http://amzn.to/awZ2qj #climate

11:42 AM Apr 19th via web
Retweeted by 43 people

Al Gore

http://www.huffingtonpost.com/al-gore/the-latest-must-read-gree_b_543449.html

Al Gore
Fmr. Vice President; Chairman, Current TV
Posted: April 19, 2010 05:01 PM

The Latest Must-Read Green Book

Joe Romm is one of the most important and influential voices fighting for an end to the climate crisis. His blog, Climate Progress, is a must read.

Romm just published an important new book, titled Straight Up: America's Fiercest Climate Blogger Takes on the Status Quo Media, Politicians, and Clean Energy Solutions. In the book, Romm "cuts through the misinformation and presents the truth about humanity's most dire threat. His analysis is based on sophisticated knowledge of renewable technologies, climate impacts, and government policy, written in a style everyone can understand."

If you are interested in the fight to solve the climate crisis, I recommend you read this book.

Cross-posted from Al Gore's Blog

Wind Power Myths Debunked

November/December 2009

Michael Milligan, Kevin Porter, Edgar DeMeo, Paul Denholm, Hannele Holttinen, Brendan Kirby, Nicholas Miller, Andrew Mills, Mark O’Malley, Matthew Schuerger, and Lennart Soder

IEEE Power and Energy Magazine

The natural variability of wind power makes it different from other generating technologies, which can give rise to questions about how wind power can be integrated into the grid successfully. This article aims to answer several important questions that can be raised with regard to wind power. Although wind is a variable resource, grid operators have experience with managing variability that comes from handling the variability of load. As a result, in many instances the power system is equipped to handle variability. Wind power is not expensive to integrate, nor does it require dedicated backup generation or storage. Developments in tools such as wind forecasting also aid in integrating wind power. Integrating wind can be aided by enlarging balancing areas and moving to subhourly sched- uling, which enable grid operators to access a deeper stack of generating resources and take advantage of the smooth- ing of wind output due to geographic diversity. Continued improvements in new conventional-generation technolo- gies and the emergence of demand response, smart grids, and new technologies such as plug-in hybrids will also help with wind integration.

In June 2004, it was announced that a new PBMR would be built at Koeberg, South Africa by Eskom, the government-owned electrical utility.<4> There is opposition to the PBMR from groups such as Koeberg Alert and Earthlife Africa, the latter of which has sued Eskom to stop development of the project.<5> In September 2009 the demonstration power plant was postponed indefinitely.<6> In February 2010 the South African government stopped funding of the PBMR because of a lack of customers and investors.

http://en.wikipedia.org/wiki/Pebble_bed_reactor

http://en.wikipedia.org/wiki/Integral_Fast_Reactor#History

IFR opponents also presented a report<12> by the DOE's Office of Nuclear Safety regarding a former Argonne employee's allegations that Argonne had retaliated against him for raising concerns about safety, as well as about the quality of research done on the IFR program. The report received international attention, with a notable difference in the coverage it received from major scientific publications. The British journal Nature entitled its article "Report backs whistleblower", and also noted conflicts of interest on the part of a DOE panel that assessed IFR research.<13>. In contrast, the article that appeared in Science was entitled "Was Argonne Whistleblower Really Blowing Smoke?".<14> Remarkably, that article did not disclose that the Director of Argonne National Laboratories, Alan Schriesheim, was a member of the Board of Directors of Science's parent organization, the American Association for the Advancement of Science.<15>

The result of our detailed analysis of the relative merits of these representative
fuel cycles with respect to key evaluation criteria can be summarized as follows:
The once through cycle has advantages in cost, proliferation, and fuel cycle
safety, and is disadvantageous only in respect to long-term waste disposal; the
two closed cycles have clear advantages
only in long-term aspects of
waste disposal, and disadvantages in
cost, short-term waste issues, proliferation
risk, and fuel cycle safety. (See
Table.) Cost and waste criteria are
likely to be the most crucial for determining
nuclear power’s future.

We have not found, and based on
current knowledge do not believe it is
realistic to expect, that there are new
reactor and fuel cycle technologies
that simultaneously overcome the
problems of cost, safety, waste, and
proliferation.

Our analysis leads to a significant conclusion: The once-through fuel cycle best
meets the criteria of low costs and proliferation resistance. Closed fuel cycles
may have an advantage from the point of view of long-term waste disposal
and, if it ever becomes relevant, resource extension. But closed fuel cycles will
be more expensive than once-through cycles, until ore resources become very
scarce. This is unlikely to happen, even with significant growth in nuclear
power, until at least the second half of this century, and probably considerably
later still. Thus our most important recommendation is:
This recommendation implies a major re-ordering of priorities of the U.S.
Department of Energy nuclear R&D programs.

http://belfercenter.ksg.harvard.edu/experts/5/john_m_deutch.html

John M. Deutch

International Council Member, Belfer Center for Science and International Affairs

Member of the Board, Belfer Center for Science and International Affairs

Experience

John M. Deutch is an Institute Professor at the Massachusetts Institute of Technology. He served as Director of Central Intelligence from May 1995–December 1996. From 1994–1995, he served as Deputy Secretary of Defense and served as Undersecretary of Defense for Acquisition and Technology from 1993–1994. John Deutch has also served as Director of Energy Research (1977–1979), Acting Assistant Secretary for Energy Technology (1979), and Undersecretary (1979–1980) in the United States Department of Energy.

In addition, John Deutch has served on the President's Nuclear Safety Oversight Committee (1980–1981); the President's Commission on Strategic Forces (1983); the White House Science Council (1985–1989); the President's Intelligence Advisory Board (1990–1993); the President's Commission on Aviation Safety and Security (1996); and the President's Commission on Reducing and Protecting Government Secrecy (1996). He currently is a member of the President's Committee of Advisors on Science and Technology (1997) and the Chairman of the President's Commission to Assess the Organization of the Federal Government to Combat the Proliferation of Weapons of Mass Destruction (1998). Dr. Deutch serves as director for the following publicly held companies: Ariad Pharmaceutical, Citicorp, CMS Energy, Cummins, Raytheon, and Schlumberger Ltd.

Dr. Deutch has been a member of the MIT faculty since 1970 and has served as Chairman of the Department of Chemistry, Dean of Science, and Provost. Dr. Deutch has published over 120 technical publications in physical chemistry, as well as numerous publications on technology, international security, and public policy issues.

Congressional Record: June 30, 1994

<snip>

Mr. KERRY. Mr. President, a few moments before the quorum call was
put into place, the Senator from Idaho asked Senators to listen
carefully to this debate, because it is about the future, the future of
nuclear power, and about the interests of the United States with
respect to the control of plutonium.

<snip>

The reality of the ALMR, the advanced liquid metal reactor, is that
it is a waste and that it is a danger, that it is fiscally
irresponsible, scientifically irresponsible, and irresponsible with
respect to arms control and nuclear waste. And every single independent
study--independent study--confirms what I have just said: OTA, National
Academy of Sciences, GAO, and so forth.

Now let me frame this debate, if I may, by reading a letter from the
President of the United States sent to me yesterday. I will just read
the first paragraph which is relevant.



<snip>

The question is squarely before the U.S. Senate: Do we have the
courage and the foresight to be willing to cut a program that every
single analysis has deemed a waste, which the President does not want,
which the Secretary of Energy does not want, and which so clearly
threatens the proliferation concerns of this country?

<snip>

This kind of irresponsible effort for fundamental pork barrel
purposes undercuts every single effort of the United States in the
international community.

<snip>

My colleagues are going to come to the floor and say you can
eliminate all of that because this technology is going to chew it all
up. Wrong. Wrong. The National Academy of Sciences tells you: Wrong and
unnecessary. That is the most important thing I ask colleagues to focus
on. When we come to the floor of the Senate and we are asked to make a
judgment about a program--you may have the most incredibly highfalutin,
wonderful program of creative technology, but it could be absolutely
unnecessary because you have a far simpler, more readily available,
safer technology at your hands. And that is precisely what we have.

<snip>

This is not a vote for or against nuclear power and it should not be
confused as that. I support light water reactor technology. I support
the advanced light water technology that is proposed in this bill.

<snip>

Thorium Fuel: No Panacea for Nuclear Power
By Arjun Makhijani and Michele Boyd

A Fact Sheet Produced by the Institute for Energy and Environmental Research and
Physicians for Social Responsibility


Thorium “fuel” has been proposed as an alternative to uranium fuel in nuclear reactors. There are not “thorium reactors,” but rather proposals to use thorium as a “fuel” in different types of reactors, including existing light-water reactors and various fast breeder reactor designs.

Thorium, which refers to thorium-232, is a radioactive metal that is about three times more abundant than uranium in the natural environment. Large known deposits are in Australia, India, and Norway. Some of the largest reserves are found in Idaho in the U.S. The primary U.S. company advocating for thorium fuel is Thorium Power (www.thoriumpower.com). Contrary to the claims made or implied by thorium proponents, however, thorium doesn’t solve the proliferation, waste, safety, or cost problems of nuclear power, and it still faces major technical hurdles for commercialization.

Not a Proliferation Solution
Thorium is not actually a “fuel” because it is not fissile and therefore cannot be used to start or sustain a nuclear chain reaction. A fissile material, such as uranium-235 (U-235) or plutonium-239 (which is made in reactors from uranium-238), is required to kick-start the reaction. The enriched uranium fuel or plutonium fuel also maintains the chain reaction until enough of the thorium target material has been converted into fissile uranium-233 (U-233) to take over much or most of the job. An advantage of thorium is that it absorbs slow neutrons relatively efficiently (compared to uranium-238) to produce fissile uranium-233. The use of enriched uranium or plutonium in thorium fuel has proliferation implications. Although U-235 is found in nature, it is only 0.7 percent of natural uranium, so the proportion of U-235 must be industrially increased to make “enriched uranium” for use in reactors. Highly enriched uranium and separated plutonium are nuclear weapons materials.

In addition, U-233 is as effective as plutonium-239 for making nuclear bombs. In most proposed thorium fuel cycles, reprocessing is required to separate out the U-233 for use in fresh fuel. This means that, like uranium fuel with reprocessing, bomb-making material is separated out, making it vulnerable to theft or diversion. Some proposed thorium fuel cycles even require 20% enriched uranium in order to get the chain reaction started in existing reactors using thorium fuel. It takes 90% enrichment to make weapons‐usable
uranium, but very little additional work is needed to move from 20% enrichment to 90% enrichment. Most of the separative work is needed to go from natural uranium, which has 0.7% uranium-235 to 20% U-235.

It has been claimed that thorium fuel cycles with reprocessing would be much less of a proliferation risk because the thorium can be mixed with uranium-238. In this case, fissile uranium-233 is also mixed with non-fissile uranium-238. The claim is that if the uranium-238 content is high enough, the mixture cannot be used to make bombs without a complex uranium enrichment plant. This is misleading. More uranium-238 does dilute the uranium-233, but it also results in the production of more plutonium-239 as the reactor operates. So the proliferation problem remains – either bomb-usable uranium-233 or bomb-usable plutonium is created and can be separated out by reprocessing.

Further, while an enrichment plant is needed to separate U-233 from U-238, it would take less separative work to do so than enriching natural uranium. This is because U-233 is five atomic weight units lighter than U-238, compared to only three for U-235. It is true that such enrichment would not be a straightforward matter because the U-233 is contaminated with U-232, which is highly radioactive and has very radioactive radionuclides in its decay chain. The radiation-dose-related problems associated with separating U-233 from U-238 and then handling the U-233 would be considerable and more complex than enriching natural uranium for the purpose of bomb making. But in principle, the separation can be done, especially if worker safety is not a primary concern; the resulting U-233 can be used to make bombs. There is just no way to avoid proliferation problems associated with thorium fuel cycles that involve reprocessing. Thorium fuel cycles without reprocessing would offer the same temptation to reprocess as today’s once-through uranium fuel cycles.

Not a Waste Solution

Proponents claim that thorium fuel significantly reduces the volume, weight and long-term radiotoxicity of spent fuel. Using thorium in a nuclear reactor creates radioactive waste that proponents claim would only have to be isolated from the environment for 500 years, as opposed to the irradiated uranium-only fuel that remains dangerous for hundreds of thousands of years. This claim is wrong. The fission of thorium creates long-lived fission products like technetium-99 (half-life over 200,000 years). While the mix of fission products is somewhat different than with uranium fuel, the same range of fission products is created. With or without reprocessing, these fission products have to be disposed of in a geologic repository.

If the spent fuel is not reprocessed, thorium-232 is very-long lived (half-life:14 billion years) and its decay products will build up over time in the spent fuel. This will make the spent fuel quite radiotoxic, in addition to all the fission products in it. It should also be noted that inhalation of a unit of radioactivity of thorium-232 or thorium-228 (which is also present as a decay product of thorium-232) produces a far higher dose, especially to certain organs, than the inhalation of uranium containing the same amount of radioactivity. For instance, the bone surface dose from breathing the an amount (mass) of insoluble thorium is about 200 times that of breathing the same mass of uranium.

Finally, the use of thorium also creates waste at the front end of the fuel cycle. The radioactivity associated with these is expected to be considerably less than that associated with a comparable amount of uranium milling. However, mine wastes will pose long-term hazards, as in the case of uranium mining. There are also often hazardous non-radioactive metals in both thorium and uranium mill tailings.

Ongoing Technical Problems
Research and development of thorium fuel has been undertaken in Germany, India, Japan, Russia, the UK and the U.S. for more than half a century. Besides remote fuel fabrication and issues at the front end of the fuel cycle, thorium-U-233 breeder reactors produce fuel (“breed”) much more slowly than uranium-plutonium-239 breeders. This leads to technical complications. India is sometimes cited as the country that has successfully developed thorium fuel. In fact, India has been trying to develop a thorium breeder fuel cycle for decades but has not yet done so commercially.

One reason reprocessing thorium fuel cycles haven’t been successful is that uranium-232 (U-232) is created along with uranium-233. U-232, which has a half-life of about 70 years, is extremely radioactive and is therefore very dangerous in small quantities: a single small particle in a lung would exceed legal radiation standards for the general public. U-232 also has highly radioactive decay products. Therefore, fabricating fuel with U-233 is very expensive and difficult.

Not an Economic Solution

Thorium may be abundant and possess certain technical advantages, but it does not mean that it is economical. Compared to uranium, thorium fuel cycle is likely to be even more costly. In a once-through mode, it will need both uranium enrichment (or plutonium separation) and thorium target rod production. In a breeder configuration, it will need reprocessing, which is costly. In addition, as noted, inhalation of thorium-232 produces a higher dose than the same amount of uranium-238 (either by radioactivity or by weight).

Reprocessed thorium creates even more risks due to the highly radioactive U-232 created in the reactor. This makes worker protection more difficult and expensive for a given level of annual dose. Finally, the use of thorium also creates waste at the front end of the fuel cycle. The radioactivity associated with these is expected to be considerably less than that associated with a comparable amount of uranium milling. However, mine wastes will pose long-term hazards, as in the case of uranium mining. There are also often hazardous non-radioactive metals in both thorium and uranium mill tailings.

Fact sheet completed in January 2009
Updated July 2009