Fuel Fuel costs account for about 28% of a nuclear plant's operating expenses. Doubling the price of uranium would add about 10% to the cost of electricity produced in existing nuclear plants, and about half that much to the cost of electricity in future power plants. The cost of raw uranium contributes about $0.0015/kWh to the cost of nuclear electricity, while in breeder reactors the uranium cost falls to $0.000015/kWh. Nuclear plants require
fissile fuel. Generally, the fuel used is
uranium, although other materials may be used (See
MOX fuel). In 2005, prices on the world market for uranium averaged US$20/lb (US$44.09/kg). On 2007-04-19, prices reached US$113/lb (US$249.12/kg). On 2008-07-02, the price had dropped to $59/lb. As of 2008, mining activity was growing rapidly, especially from smaller companies, but putting a uranium deposit into production takes 10 years or more. According to the
World Nuclear Association, "the world's present measured resources of uranium (5.7 Mt) in the cost category less than three times present spot prices and used only in conventional reactors, are enough to last for about 90 years. This represents a higher level of assured resources than is normal for most minerals. Further exploration and higher prices will certainly, on the basis of present geological knowledge, yield further resources as present ones are used up." The amount of uranium present in all currently known conventional reserves alone (excluding the huge quantities of currently-uneconomical uranium present in "unconventional" reserves such as phosphate/phosphorite deposits, seawater, and other sources) is enough to last over 200 years at current consumption rates.
Waste disposal All nuclear plants produce radioactive waste. In order to pay for the cost of storing, transporting and disposing these wastes in a permanent location in the United States, a surcharge of a tenth of a
cent per kilowatt-hour is added to electricity bills. Roughly one percent of electrical utility bills in provinces using nuclear power are diverted to fund nuclear waste disposal in Canada. The disposal of
low level waste reportedly costs around £2,000/m³ in the UK.
High level waste costs somewhere between £67,000/m³ and £201,000/m³. General division is 80%/20% of low level/high level waste, and one reactor produces roughly 12 m³ of high level waste annually.
Decommissioning At the end of a nuclear plant's lifetime, the plant must be decommissioned. This entails either dismantling, safe storage or entombment. In the United States, the
Nuclear Regulatory Commission (NRC) requires plants to finish the process within 60 years of closing. Since it costs around $500 million or more to shut down and decommission a plant, the NRC requires plant owners to set aside money when the plant is still operating to pay for the future shutdown costs. Decommissioning a reactor that has undergone a meltdown is inevitably more difficult and expensive.
Three Mile Island was decommissioned 14 years after its incident for $837 million. The cost of the
Fukushima disaster cleanup is not yet known, but has been estimated to cost around $100 billion.
Proliferation and terrorism A 2011 report for the
Union of Concerned Scientists stated that "the costs of preventing
nuclear proliferation and
terrorism should be recognized as negative externalities of civilian nuclear power, thoroughly evaluated, and integrated into economic assessments—just as global warming emissions are increasingly identified as a cost in the economics of coal-fired electricity". "Construction of the ELWR was completed in 2013 and is optimized for civilian electricity production, but it has "dual-use" potential and can be modified to produce material for nuclear weapons."
Safety in 1986, at a commemoration 25 years after the nuclear accident, as well as for the
Fukushima nuclear disaster of 2011.
Nancy Folbre, an economist at the University of Massachusetts, has questioned the economic viability of nuclear power following the
2011 Japanese nuclear accidents: The proven dangers of nuclear power amplify the economic risks of expanding reliance on it. Indeed, the stronger regulation and improved safety features for nuclear reactors called for in the wake of the Japanese disaster will almost certainly require costly provisions that may price it out of the market. The cascade of problems at Fukushima, from one reactor to another, and from reactors to fuel storage pools, will affect the design, layout and ultimately the cost of future nuclear plants.
Insurance Insurance available to the operators of nuclear power plants varies by nation. The
worst case nuclear accident costs are so large that it would be difficult for the private insurance industry to carry the size of the risk, and the premium cost of full insurance would make nuclear energy uneconomic. Nuclear power has largely worked under an insurance framework that limits or structures accident liabilities in accordance with the
Paris convention on nuclear third-party liability, the Brussels supplementary convention, the
Vienna convention on civil liability for nuclear damage, and in the United States the
Price-Anderson Act. It is often argued that this potential shortfall in liability represents an external cost not included in the cost of nuclear electricity. In Canada, the Canadian Nuclear Liability Act requires nuclear power plant operators to obtain $650 million (CAD) of liability insurance coverage per installation regardless of the number of individual reactors present, starting in 2017 (up from the prior $75 million requirement established in 1976), increasing to $750 million in 2018, to $850 million in 2019, and to $1 billion in 2020. Claims beyond the insured amount would be assessed by a government appointed but independent tribunal, and paid by the federal government. In the
UK, the Nuclear Installations Act 1965 governs liability for nuclear damage for which a UK nuclear licensee is responsible. The limit for the operator is £140 million. In the United States, the
Price-Anderson Act has governed the insurance of the nuclear power industry since 1957. Owners of nuclear power plants are required to pay a premium each year for the maximum obtainable amount of private insurance ($450 million) for each licensed reactor unit. This primary or "first tier" insurance is supplemented by a second tier. In the event a nuclear accident incurs damages in excess of $450 million, each licensee would be assessed a prorated share of the excess up to $121,255,000. With 104 reactors currently licensed to operate, this secondary tier of funds contains about $12.61 billion. This results in a maximum combined primary+secondary coverage amount of up to $13.06 billion for a hypothetical single-reactor incident. If 15 percent of these funds are expended, prioritization of the remaining amount would be left to a federal district court. If the second tier is depleted, Congress is committed to determine whether additional disaster relief is required. In July 2005,
Congress extended the Price-Anderson Act to newer facilities. == Cost per kWh ==