Dispute over disposal of nuclear waste brewing between power companies

The nuclear option: size of the challenges

• If world electricity demand grows 2% /year until 2050 and nuclear share of electricity supply is to rise from 1/6 to 1/3...
–nuclear capacity would have to grow from 350 GWe in 2000 to 1700 GWe in 2050;
– this means 1,700 reactors of 1,000 MWe each.

• If these were light-water reactors on the once-through fuel cycle...
---–enrichment of their fuel will require ~250 million Separative Work Units (SWU);
---–diversion of 0.1% of this enrichment to production of HEU from natural uranium would make ~20 gun-type or ~80 implosion-type bombs.

• If half the reactors were recycling their plutonium...
---–the associated flow of separated, directly weapon - usable plutonium would be 170,000 kg per year;
---–diversion of 0.1% of this quantity would make ~30 implosion-type bombs.

• Spent-fuel production in the once-through case would be...
---–34,000 tonnes/yr, a Yucca Mountain every two years.

Conclusion: Expanding nuclear enough to take a modest bite out of the climate problem is conceivable, but doing so will depend on greatly increased seriousness in addressing the waste-management & proliferation challenges.


Mitigation of Human-Caused Climate Change
John P. Holdren

The renewable option: Is it real?

SUNLIGHT: 100,000 TW reaches Earth’s surface (100,000 TWy/year = 3.15 million EJ/yr), 30% on land.
Thus 1% of the land area receives 300 TWy/yr, so converting this to usable forms at 10% efficiency would yield 30 TWy/yr, about twice civilization’s rate of energy use in 2004.

WIND: Solar energy flowing into the wind is ~2,000 TW.
Wind power estimated to be harvestable from windy sites covering 2% of Earth’s land surface is about twice world electricity generation in 2004.

BIOMASS: Solar energy is stored by photosynthesis on land at a rate of about 60 TW.
Energy crops at twice the average terrestrial photosynthetic yield would give 12 TW from 10% of land area (equal to what’s now used for agriculture).
Converted to liquid biofuels at 50% efficiency, this would be 6 TWy/yr, more than world oil use in 2004.

Renewable energy potential is immense. Questions are what it will cost & how much society wants to pay for environmental & security advantages.

G. Reprocessing and spent fuel stocks from existing U.S. reactors
As we have seen, statements that 90 or 95 percent of the material in spent fuel can be used are completely invalid without breeder reactors. In this section we will examine some of the implications of a policy that seeks to deal with existing spent fuel by trying to convert the mass of the material into fuel and using it for energy, assuming that breeder reactors will work and can be deployed on a large scale.

We start with a heuristic calculation. A 1,000-megawatt nuclear power reactor fissions about one metric ton of heavy metal per year in the course of energy generation. At present, there are over 60,000 metric tons of spent fuel in the United States. With reactor re-licensing, the total amount of spent fuel could amount to well over 100,000 metric tons by the time the reactors are retired; 95-plus percent of the content of this spent fuel is uranium or transuranic elements (mainly plutonium). We will use a round number of 100,000 metric tons92 of uranium and plutonium content in spent fuel that would be converted into fuel. This corresponds approximately to statements that 90 or 95 percent of existing spent fuel has “energy value” and hence should not be regarded as waste. For instance, such a scheme would appear to be the one that Dr. Miller had in mind and that NRC Commissioner Bill Magwood made explicit in his discussions of spent fuel management.93

Setting aside for the moment a variety of difficult issues, including those associated with the rate of conversion of uranium-238 into plutonium, it is easy to see that it would take 100,000 reactor years (assuming 1,000 megawatt reactors) to convert the heavy metal content of spent fuel from the existing fleet of U.S. power reactors into fission products in a manner that extracts essentially all the physically possible energy value in it.

Assume a reactor operating life of 50 years, accumulating 100,000 reactor years would mean building 2,000 reactors to extract the energy in the total spent fuel from the existing fleet of reactors. This is about 20 times the size of the existing U.S. nuclear power system. It is four times the total electricity generation of the United States and seven or eight times the baseload requirements under the present centralized electricity dispatch system. If the material is consumed in a smaller number of reactors, the time to consume it would be proportionally increased. For instance, it would take 200 years to consume the material in 500 reactors.

THE MYTHOLOGY AND MESSY REALITY OF NUCLEAR FUEL REPROCESSING (pg 37)
Arjun Makhijani, Ph.D.

Japan’s Plutonium Breeder Reactor and its Fuel Cycle
Tatsujiro Suzuki
This paper reviews the history, status, and probable future of fast reactor and associated fuel cycle development in Japan. The fast breeder reactor and its closed fuel cycle have been the cornerstone of Japan’s nuclear-energy development program since the 1950s. For economic, technological, and political reasons, Japan’s development and implementation of these technologies are significantly delayed. The budget for fast breeder reactor development has steadily declined since the mid-1990s, and its commercialization target has slipped from the 1980s to the 2050s. An accident at the Monju prototype reactor contributed to these delays and triggered a fundamental shift from research and development (R&D) and early commercialization to an emphasis on advanced fuel cycles.

Nevertheless, Japan is still committed to fast-reactor development.** This paper examines the motivation for its continued commitment to a fast reactor program and concludes that several non-technological factors, such as bureaucratic inertia, commitments to local communities, and an absence of R&D oversight have contributed to this entrenched position. Japan is currently reorganizing its R&D programs with the goal of operating a demonstration breeder reactor by about 2025. This effort is in response to the government sponsored Nuclear Power National Plan and the Bush Administration’s Global Nuclear Energy Partnership Program (GNEP). Breeder R&D programs face significant obstacles, such as plutonium-stockpile management, spent fuel management, fuel cycle technologies, and arrangements for cost and risk sharing between industry, national and local governments. As a result, it is likely that fast breeder reactor programs will continue to slip.... (Pg 53)

Japan freezes fast breeder plans
- September 28, 2011

Monju, Japan’s prototype fast breeder reactor, has had its research budget slashed. This might not come as a big surprise, given the anti-nuke sentiment in Japan and the tattered state of its nuclear energy policy. Still, with this latest blow, the woeful state of the ill-fated reactor is all the more striking. It could be maintained — with the help of a one-off Y20 billion yen (US$262 million) allocation — but the annual research budget will be cut 70%~80% from its previous Y10 billion.

Monju reached criticality in 1994 but was shut down the following year because of a fire triggered by a sodium coolant leak. It took the government over 14 years to demonstrate safety, overcome scandals related to tampered video images, and garner local support for restarting operations. But then, three months after it did so in May 2010, something happened that is still difficult to fathom. In August, 3.3-tonne device fell into the reactor’s inner vessel, cutting off access to the plutonium and uranium fuel rods. After a couple failed attempts, they finally dislodged the device in June 2011.

Monju was to be the cornerstone of Japan’s plans to use MOX (mixed oxide) fuel, but those plans seem to have disintegrated...

Big Risks, Better Alternatives
An Examination of Two Nuclear Energy Projects in the U.S.
October 6, 2011

Key Findings
Our analysis finds that there are major risks associated with the construction of both the Levy and Vogtle projects. While the AP1000 reactor represents a more standardized design than existing U.S. reactors, it has never been built in this country nor completed in any country. Nuclear power construction is still a very complicated process with numerous unknowns that can negatively impact plant economics. Risks for these projects include cost escalation, construction and regulatory delays, and lack of transparency (for the Vogtle project), all of which could lead to much higher costs to ratepayers. Using the companies’ current cost estimates:
- By 2021, the Levy project will add at least $718 per year to the bill of a typical Progress Energy residential customer using 1,100 kWh per month; and
- By 2018, the Vogtle project will add at least $120 per year to the bill of a Georgia Power residential customer using 1,000 kWh per month.

If history is our guide, these cost estimates are likely to increase dramatically over time. The anticipated cost and rate impact for the Vogtle project, in particular, could increase significantly; the redaction of all cost and schedule data for this project has hindered independent analysis of the underlying assumptions that have allowed Georgia Power to maintain old cost estimates despite major changes in economic and regulatory conditions over the past five years. This lack of transparency puts Georgia Power’s ratepayers at significant risk for major price hikes in the coming years.

By comparison, based on publically available data, there are alternative options readily available to Progress Energy and Georgia Power that could meet consumers’ energy needs and be implemented at a lower cost, with far less risk to ratepayers. Energy sales growth for both of these companies has slowed considerably compared to earlier projections, making it is possible to meet their future retail energy sales growth through smaller increments of alternative demand- and supply-side resources. These options include increased energy efficiency and renewable energy development.

Our analysis shows that both Florida and Georgia have significant room for improvement when it comes to energy efficiency investment. According to the American Council for an Energy-Efficient Economy (ACEEE), in 2010, Georgia ranked 37th overall and Florida ranked 30th overall among U.S. states as benchmarked against six energy efficiency categories.4
- In Florida: The Florida Public Service Commission (PSC) recently approved scaled-back demand-side management plans for Progress that are projected to capture a maximum of 2 percent energy savings over a 10-year period.5 If Progress were to pursue an EE target of 15 percent cumulative load reduction over the same timeframe, it could maintain its energy load below peak 2006 levels based on its 2010 10-Year Site Plan retail sales forecast.
- In Georgia: The state currently has no energy efficiency targets. Recent reports support the fact that the state has large, untapped energy efficiency potential.

Both states also have significant potential for increased development of renewable energy resources...