Tag: nuclear power

The transition towards clean energy in combination with a shortfall in supply has seen the price of raw uranium, also known as ‘yellowcake’, rise almost 60 per cent in recent weeks. It is now trading at over $50 a pound – a nine-year high. The market has been described as being at a ‘tipping point’. Given the recent boom in the market, the current conditions could tip the balance towards an era of rising uranium prices.

What is uranium?

Uranium is a heavy metal which has been used as a source of concentrated energy for over 60 years. Uranium ore can be mined from underground, milled, and then sold. It is then used in a nuclear reactor for electricity generation. About 10% of the world’s electricity is generated from uranium in nuclear reactors. There are some 445 nuclear reactors operating in 32 countries. It is the most energy-dense and efficient fuel source we have, with just ten uranium pellets able to power the average household for an entire year.

In March 2011, Japan’s most powerful earthquake on record triggered a tsunami, which then caused a meltdown at a nuclear power plant in Fukushima. It forced residents from their homes as radiation leaked from the plant. Since the Fukushima accident, uranium prices had been on a downtrend trend – enough to force several miners to suspend or scale back operations.

However, there has been a 42 per cent increase in the price of the metal in the first nine months of 2021 alone.

Demand for uranium

Since launching in July, a new investment trust, run by Canadian asset manager Sprott, has snapped up about 6m pounds of physical uranium, worth about $240m. This aggressive buying has helped push prices of uranium to more than $40 per pound, up from $30 at the start of the year. In the first part of September alone, prices surged by around 40%, outperforming all other major commodities. In just a few weeks, millions of pounds of supply were scooped up by the Sprott Physical Uranium Trust. This puts pressure on utilities that need to secure supplies of the commodity for electricity generation.

This increased demand is occurring at precisely the same time as countries and companies around the world are committing to net-zero carbon targets. As a result, nuclear power companies are now facing competition for supplies of uranium from financial investors, who are betting on sharply higher prices and demand for the radioactive material used to fuel reactors. This boost in demand is said to be due to uranium being used as a low-carbon energy source, despite the radioactive waste problem that comes with it. Investors are betting that nuclear power will be a key part of the move away from fossil fuels.

Production from world uranium mines has in recent years supplied 90% of the requirements of power utilities for uranium, with the current global mine supply expected to be about 125m pounds for 2021. In addition, there are secondary sources such as commercial and military stockpiles. However, according to the World Nuclear Association, demand for uranium is expected to climb from about 162m pounds this year to 206m pounds in 2030, and to 292m pounds by 2040. This is largely driven by increased power generation in China. China is planning a big increase in its nuclear power capacity over the next decade as the country seeks to cut its emissions.

Supply of uranium

Although uranium is relatively abundant in the Earth’s crust, not all uranium deposits are economically recoverable. While some countries have uranium resources that can be mined profitably when prices are low, others do not. Kazakhstan is the largest producer of uranium and in 2019 produced more uranium than the second, third, and fourth-largest producers combined.

The big issue is that supply to the market is falling significantly. For deliveries that would start in 2022, Kazakh producer, Kazatomprom, is now discussing the possibility of supplying the metal directly to Sprott. However, it also warned of the risk that its mines would not reach their output target for 2021, and it said earlier this year that it would keep its production at reduced levels through 2023. In addition to this, the recent surge in buying is also reducing the inventories that accumulated after the Fukushima accident.

The supply of uranium is set to fall 15 per cent by 2025 and by 50 per cent by 2030. This is mainly due to a lack of investment in new mines. The lack of new uranium mines will mean the price has to move higher. Namibian mines, accounting for 8 per cent of world supply, are approaching the end of their lives. Cameco of Canada, another important source, has shut one large pit because of uneconomic prices. According to BMO Capital, a mine supply deficit since 2019 will continue.

Supply has also been affected by the pandemic. The boom in demand has coincided with historically low prices and pandemic-driven mine disruptions, prompting uranium producers to buy from the spot market to fulfil long-term contracts with consumers. Some of the largest mining operations in Canada and Kazakhstan had to suspend production temporarily due to a shortage of workers.

Adding to the security of supply concerns is the role of commercial and state-owned entities in the uranium market. Uranium is a highly trade-dependent commodity with international trade policies highlighting the disconnect between where uranium is produced and where it is consumed. About 80% of primary production comes from countries that consume little-to-no uranium, and nearly 90% of uranium consumption occurs in countries that have little-to-no primary production. As a result, government-driven trade policies can be particularly disruptive for the uranium market. It is argued that the risk to uranium supply may create a renewed focus on ensuring availability of long-term supply to fuel nuclear reactors.

The role of financial players

Financial players have been accelerating the recent recovery in the price of uranium, with large-scale speculative buying and withholding of supply. But it can be argued that this would not have occurred if there were not a fundamental and substantial shortage.

If investors keep buying uranium, analysts expect utility companies will come under pressure to replace long-term supply agreements before they expire. At the moment, long-term contracts cover 98 per cent of the uranium needed by US utility companies. But that figure drops to 84 per cent next year, and 55 per cent by 2025, according to uranium investment company, Yellow Cake.

As annual supply declines, demand for uranium from producers and financial players increases, and with trade policy potentially restricting access to some markets, it is believed the pounds available in the spot market will not be adequate to satisfy the growing backlog of long-term demand. As a result, companies expect there will be increased competition to secure uranium under long-term contracts on terms that will ensure the availability of reliable primary supply to meet growing demand.

What will the future look like?

Many countries are turning their attention to nuclear power in order to become net-zero economies. Even in Japan, nuclear generation has slowly been returning. It is argued that nuclear power is needed to some degree for the country to achieve its pollution-curbing goals. However, not all nations are re-embracing nuclear. Germany, for example, is set to shut its last reactor next year.

The concern is whether the recent gains in investor demand is enough to underpin the market. It can be argued that even before the recent price rally started, demand for uranium from the investment sector was already growing. However, observers of the market have suggested that just as quickly as uranium skyrocketed, prices may now be hitting the brakes. Producer stocks that got swept up in the frenzy seem to have peaked. In addition, the world’s top uranium miner Kazatomprom has warned that the recent price action was being fuelled by financial investors rather than the utilities that use the radioactive metal as fuel in their reactors. On the other hand, it is argued that this pickup in the spot market will be the catalyst to push more utilities to get involved in term contracting.

Despite the impact of the pandemic on global energy demand, it is now growing again. Gas and other energy shortages are being seen and the price of gas has been rising rapidly. This rise in energy prices plus a focus on carbon-free generation is likely to continue driving demand for nuclear power and hence for uranium. In addition, producers have warned of supply shortages in the long term as investors scoop up physical inventory and new mines are not starting quickly enough. Thus nuclear’s growing role in the clean energy transition, in addition to a supply shortfall, could turn the tide for the uranium industry.




  1. Using the uranium market as an example, describe the relationship between an increase in demand and the market price.
  2. Explain whether the supply of uranium would be price elastic or inelastic in (a) the short run; (b) the long run.
  3. What is the role of speculation in determining the recent movements in the price of uranium and likely future price movements?
  4. Given your answers to the above questions, draw supply and demand diagrams to illustrate (a) the recent increase in the market price of uranium; (b) the likely price of uranium in five years from now.

The UK government has finally given the go-ahead to build the new Hinkley C nuclear power station in Somerset. It will consist of two European pressurised reactors, a relatively new technology. No EPR plant has yet been completed, with the one in the most advanced stages of construction at Flamanville in France, having experienced many safety and construction problems. This is currently expected to be more than three times over budget and at least six years behind its original completion date of 2012.

The Hinkley C power station, first proposed in 2007, is currently estimated to cost £18 billion. This cost will be borne entirely by its builder, EDF, the French 85% state-owned company, and its Chinese partner, CGN. When up and running – currently estimated at 2025 – it is expected to produce around 7% of the UK’s electricity output.

On becoming Prime Minister in July 2016, Theresa May announced that the approval for the plant would be put on hold while further investigation of its costs, benefits, security concerns, technological issues and safeguards was conducted. This has now been completed and approval has been granted subject to new conditions. The main one is that the government “will be able to prevent the sale of EDF’s controlling stake prior to the completion of construction”. This will allow the government to prevent change of ownership during the construction phase. Thus, for example, EDF, would not be allowed to sell its share of Hinkley C to CGN, which currently has a one-third share in the project. EDF and CGN have accepted the new terms.

After Hinkley the government will have a ‘golden share’ in all future nuclear projects. “This will ensure that significant stakes cannot be sold without the Government’s knowledge or consent.”

In return for their full financing of the project, the government has guaranteed EDF and CGN a price of £92.50 per megawatt hour of electricity (in 2012 prices). This price will be borne by consumers. It will rise with inflation from now and over the first 35 years of the power station’s operation. It is expected that the Hinkley C will have a life of 60 years.

Critics point out that this guaranteed ‘strike price’ is more than double the current wholesale price of electricity and, with the price of renewables falling as technology improves, it will be an expensive way to meet the UK’s electricity needs and cut carbon emissions.

Those in favour argue that it is impossible to predict electricity prices into the distant future and that the certainty this plant will give is worth the high price by current standards.

To assess the desirability of the plant requires an assessment of its costs and benefits. In principle, this is a relatively simple process of identifying and measuring the costs and benefits, including external costs and benefits; discounting future costs and benefits to give them a present value; weighting them by their probability of occurrence; then calculating whether the net present value is positive or negative. A sensitivity analysis could also be conducted to show just how sensitive the net present value would be to changes in the value of specific costs or benefits.

In practice the process is far from simple – largely because of the huge uncertainty over specific costs and benefits. These include future wholesale electricity prices, unforeseen problems in construction and operation, and a range of political issues, such as pressure from various interest groups, and attitudes and actions of EDF and CGN and their respective governments, which will affect not only Hinkley C but other future power stations.

The articles look at the costs and benefits of this, the most expensive construction project ever in the UK, and possibly on Earth..


Hinkley Point: UK approves nuclear plant deal BBC News (15/9/16)
Hinkley Point: What is it and why is it important? BBC News, John Moylan (15/9/16)
‘The case hasn’t changed’ for Hinkley Point C BBC Today Programme, Malcolm Grimston (29/7/16)
U.K. Approves EDF’s £18 Billion Hinkley Point Nuclear Project Bloomberg, Francois De Beaupuy (14/9/16)
Hinkley Point C nuclear power station gets government green light The Guardian, Rowena Mason and Simon Goodley (15/9/16)
Hinkley Point C: now for a deep rethink on the nuclear adventure? The Guardian, Nils Pratley (15/9/16)
Hinkley Point C finally gets green light as Government approves nuclear deal with EDF and China The Telegraph, Emily Gosden (15/9/16)
UK gives go-ahead for ‘revised’ £18bn Hinkley Point plant Financial Times, Andrew Ward, Jim Pickard and Michael Stothard (15/9/16)
Hinkley Point: Is the UK getting a good deal? Financial Times, Andrew Ward (15/9/16)
Hinkley Point is risk for overstretched EDF, warn critics Financial Times, Michael Stothard (15/9/16)
Hinkley C must be the first of many new nuclear plants The Conversation, Simon Hogg (16/9/16)


Nuclear power in the UK National Audit Office, Sir Amyas Morse, Comptroller and Auditor General (12/7/16)


  1. Summarise the arguments for going ahead with Hinkley C.
  2. Summarise the objections to Hinkley C.
  3. What categories of uncertain costs and uncertain benefits are there for the project?
  4. Is the project in EDF’s interests?
  5. How will the government’s golden share system operate?
  6. How should the discount rate be chosen for discounting future costs and benefits from a project such as Hinkley C?
  7. What factors will determine the wholesale price of electricity over the coming years? In real terms, do you think it is likely to rise or fall? Explain.
  8. If nuclear power has high fixed costs and low marginal costs, how does this affect how much nuclear power stations should be used in a situation of daily and seasonal fluctuations in demand?
  9. How could ‘smart grid’ technology smooth out peaks and troughs in electricity supply and demand? How does this affect the relative arguments about nuclear power versus renewables?

The UK government has just given the go-ahead for the building of two new nuclear reactors at Hinkley Point in Somerset. The contract to build and run the power station will go to EDF, the French energy company.

The power station is estimated to cost some £14 billion to build. It would produce around 7% of the UK’s electricity. Currently the 16 nuclear reactors in the UK produce around 19%. But all except for Sizewell B in Suffolk are due to close by 2023, although the lives of some could be extended. There is thus a considerable energy gap to fill in the coming years.

Several new nuclear power stations were being considered to help fill this gap, but with rising capital costs, especially following the Fukushima disaster in Japan, potential investors pulled out of other negotiations. Hinkley Point is the only proposal left. It’s not surprising that the government wants it to go ahead.

All that remains to agree is the price that EDF can charge for the electricity generated from the power station. This price, known as the ‘strike price’, is a government-guaranteed price over the long term. EDF is seeking a 40-year deal. Some low carbon power stations, such as nuclear and offshore wind and wave power stations, have high capital costs. The idea of the strike price is to reduce the risks of the investment and make it easier for energy companies to estimate the likely return on capital.

But the strike price, which will probably be agreed at around £95 per megawatt hour (MWh), is roughly double the current wholesale price of electricity. EDF want a price of around £100 per MWh, which is estimated to give a return on capital of around 10%. The government was hoping to agree on a price nearer to £80 per MWh. Either way, this will require a huge future subsidy on the electricity generated from the plant.

There are several questions being asked about the deal. Is the strike price worth paying? Are all the costs and benefits properly accounted for, including environmental costs and benefits and safety issues? Being an extremely long-term project, are uncertainties over costs, performance of the plant, future market prices for electricity and the costs of alternative forms of power generation sufficiently accounted for? Will the strike price contravene EU competition law? Is the timescale for construction realistic and what would be the consequences of delays? The articles consider these questions and raise a number of issues in planning very long-term capital projects.


Hinkley Point: Britain’s second nuclear age given green light as planning permission is approved for first of new generation atomic power stations Independent, Michael McCarthy (19/3/13)
Will they or won’t they? New nuclear hangs in the balance ITV News, Laura Kuenssberg (19/3/13)
Hinkley Point C: deal or no deal for UK nuclear? The Telegraph, Alistair Osborne (19/3/13)
New nuclear power plant at Hinkley Point C is approved BBC News (20/3/13)
Britain’s Plans for New Nuclear Plant Approach a Decisive Point, 4 Years Late New York Times, Stanley Reed and Stephen Castle (15/3/13)
Nuclear power plans threatened by European commission investigation The Guardian (14/3/13)
New Hinkley Point nuclear power plant approved by UK government Wired, Ian Steadman (19/3/13)
Renewable energy providers to help bear cost of new UK nuclear reactors The Guardian, Damian Carrington (27/3/13)
Europe backs Hinkley nuclear plant BBC News (8/10/14)

Information/Reports/Journal Articles
Environmental permitting of Hinkley Point C Environment Agency
NNB Generation Company Limited, Radioactive Substances Regulations, Environmental Permit Application for Hinkley Point C: Chapter 7, Demonstration of Environmental Optimisation EDF
Greenhouse Gas Emission of European Pressurized Reactor (EPR) Nuclear Power Plant Technology: A Life Cycle Approach Journal of Sustainable Energy & Environment 2, J. Kunakemakorn, P. Wongsuchoto, P. Pavasant, N. Laosiripojana (2011)


  1. Compare the relative benefits of a construction subsidy and a subsidised high strike price from the perspectives of (a) the government (b) EDF.
  2. What positive and negative externalities are involved in nuclear power generation?
  3. What difficulties are there in valuing these externalities?
  4. What is meant by catastrophic risk? Why is this difficult to take account of in any cost–benefit analysis?
  5. What is meant by a project’s return on capital? Explain how discounted cash flow techniques are used to estimate this return.
  6. What should be taken into account in deciding the rate of discount to use?
  7. How should the extra jobs during construction of the plant and then in the running of the plant be valued when making the decisions about whether to go ahead?