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Snapshots from Australia’s Nuclear Options
Snapshots from Australia’s Nuclear Options
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Non-Members: Purchase the report here.
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The below snapshots refer to CEDA's research report
Australia's Nuclear Options.
What should Australia
do?
Nuclear waste: Environmental
problem or opportunity?
Australia as the world's disposal
site?
Weapons
proliferation
Nuclear
safety
Environmental
Opportunity
Economics of Nuclear Power -
expensive to build, cheap to run
Construction and Nuclear
Power
Nuclear renaissances in
command and control economies
The opportunities associated with
Small Modular Nuclear Reactors
The economic opportunities in the
nuclear fuel cycle
What should Australia
do?
Ultimately whether nuclear power is suitable for Australia will
be determined by technological advances in the near future.
Although political leadership will mean it is available as an
option if it is necessary to ensure the ongoing prosperity of
Australia.
The public policy position should be to enable the deployment of
nuclear power in Australia should it prove safe and
cost-effective.
Two key steps to enabling nuclear power deployment involve:
- Establishing a national regulatory regime to oversee and
monitor any potential deployment of nuclear power; and
- Training nuclear engineers by establishing an equivalent of the
previous School for Nuclear Engineering or the Australian School of
Nuclear Technology.
Given the potential for commercial Small Modular Nuclear
Reactors (SMRs) to be available in 2020, the Federal Government
should undertake these two steps immediately.
The costs of establishing a nuclear regulatory framework and
developing suitably qualified technicians can be considered as the
cost of purchasing a call option on greater flexibility for future
energy supply. The value of any option is critically determined by
the variability of the underlying asset. Given the uncertainty
about the cost of decarbonised energy, purchasing a nuclear call
option may prove to be an invaluable investment.
Nuclear
waste: Environmental problem or opportunity?
A major concern that many people hold is that nuclear power
generates substantial amounts of radioactive waste that will
represent a problem requiring thousands of years to resolve. This
raises an almost philosophical question about whether it is
appropriate to use uranium for energy today while endowing a
problem to untold future generations.
Fortunately this concern is not valid.
In the first instance, as Dr Tom Quirk makes clear,
existing waste products are a source of potential fuel in the
future. They are considered waste at this point because the world
lacks sufficient capacity to reprocess spent fuel. If it was
reprocessed, the amount of physical waste would drop
considerably.
In the second instance, as Professor Brook discusses, there
is the potential for the residual waste from existing nuclear power
plants (after it has been reprocessed) to be used as a fuel source
for the future generation of nuclear reactors.
So potentially Australia can sell unprocessed uranium, be paid
to store the waste from existing nuclear reactors, reprocess the
waste and sell it, take back the resulting waste a second time, and
eventually sell that waste product again. See The economic opportunities in
the nuclear fuel cycle for more details.
Australia
as the world's disposal site?
Despite having no significant involvement in the nuclear fuel
cycle beyond mining the raw material, Australia has already made a
number of very significant contributions to the nuclear industry
that are used throughout the world (refer to
Dr Quirk's chapter). For instance, Australia has made
significant technical contributions to enrichment through Silex
Systems and the disposal of spent fuel with Synroc.
Unfortunately, Australia's lack of enabling policy has resulted
in these technologies going offshore to be developed.
Australia could play a bigger role in enabling the world to
respond to climate change and helping ensure non-proliferation
through the development of a high-tech repository facility for
spent nuclear fuel. Refer to Dr
Quirk's chapter.
Weapons proliferation
Australia is a party to the Nuclear Non-Proliferation Treaty
(NPT) as a non-nuclear weapons state. The safeguards agreement
under the NPT came into force in 1974 and Australia was the first
country in the world to bring into force the Additional Protocol in
relation to this, in 1997. In addition to these international
arrangements Australia requires customer countries to have entered
a bilateral safeguards treaty which is more rigorous than NPT
arrangements. These treaties have been an obstacle to selling
uranium to India. While the United States has managed to reach a
safeguards agreement we have not. Refer to Dr
Quirk's chapter.
Nuclear power has already achieved widespread deployment and the
nuclear genie is well and truly out of the bottle. Currently the
nation of Kazakhstan is the world's largest exporter of uranium.
Limiting Australia's supply of uranium will have no influence on
the proliferation of nuclear weapons.
The biggest contribution that Australia can make to
non-proliferation and more generally enhancing the security of
nuclear power is by developing a repository for spent nuclear fuel.
This is also a significant economic opportunity for
Australia See The
economic opportunities in the nuclear fuel cycle for more
details.
Nuclear
safety
Detractors of nuclear power may consider the disaster at the
Fukushima Daiichi nuclear reactor as sufficient cause to ignore it.
However, the Fukushima Daiichi reactor was of 1960s vintage and
modern reactor designs have passive safety features that preclude
such a scenario occurring. Australia cannot afford to make policy
decisions based on technology more than 40 years old. It would be
equivalent to critiquing the rollout of the national broadband
network based on assessments of the telegraph system.
The modern Generation III reactor designs are efficient and have
a high degree of passive safety. For instance, the risk of a
meltdown as serious as the Three Mile Island incident in the US
(which resulted in no fatalities) has been assessed as extremely
low for GE-Hitachi's new Economic Simplified Boiling Water Reactor,
compared to earlier designs. Of course to demand zero is to ask the
impossible of any energy technology, given the possibility of
beyond-design-basis events, and ignores the trade-off involved in
fixing other major environmental problems with extremely high
probabilities attached. Refer to Professor Brook's
chapter.
Furthermore, the Small Modular Reactor designs can be built
underground and can incorporate significant passive features that
would enable them to withstand the environmental catastrophe
associated with Fukushima. A more comprehensive description of the
safety features of Small Modular Nuclear Reactors (SMRs) is
available in Irwin's chapter.
Environmental
Opportunity
Nuclear power is widely used throughout the world and represents
one of the most reliable means of replacing fossil fuels. Only
hydropower displaces more carbon emissions than nuclear energy, and
Australia is already utilising all of its reasonable hydropower
resources.
There are significant opportunity costs tied to any decision for
Australia to leave nuclear energy to others, and instead focus on a
narrow portfolio of unproven low-carbon electricity options. A
nation's sustainable energy future depends on choices made today.
Some countries in the developed and developing world have already
made their choice - for them, nuclear has a clear role, and the
only question is, how much? The opportunity cost of not deploying
nuclear power is higher carbon emissions. This is a reality that
the Germans will quickly discover. Having decided to wind back the
deployment of nuclear power, they are planning two-dozen new
coal-fired power stations. Refer to Professor
Brook's chapter.
Nuclear power also has important environmental benefits that
extend beyond mitigating carbon emissions. An important comparison
in exporting energy is that shipping 10,000 tonnes of yellowcake is
the energy equivalent of shipping 200 million tonnes of thermal
coal. Australia's present thermal coal exports are around 100
million tonnes. This requires between 3,000 and 4,000 voyages of
bulk carriers through environmentally sensitive regions, such as
the Great Barrier Reef. Refer to Dr Quirk's
chapter.
Economics of Nuclear Power - expensive
to build, cheap to run
Although costs vary both between and within countries, about
two-thirds of the costs of generating electricity from a nuclear
power plant are accounted for by fixed costs arising from the
construction process, with the remainder being fixed and variable
operating costs. The main fixed costs are capital repayments and
interest on loans. An allowance for decommissioning costs is
also included in this item, although the timing and precise costs
of decommissioning lack clarity. Fuel is a relatively minor
component of operating costs, because uranium is in relatively
abundant supply in terms of current requirements.
Once a nuclear power plant has been built, its construction
costs have effectively been "sunk" and it makes financial sense to
operate the plant continuously. Currently nuclear power is the
cheapest form of electricity production in most OECD countries for
existing plants.
For new nuclear power plants their competitiveness depends on
several factors, including the cost of alternative technologies, if
a country has energy security from other sources such as gas or
coal and growth of overall demand.
In general, nuclear power's front loaded cost structure is less
attractive to a private investor in a liberalised market that
values short-term returns rather than a government-owned utility
that has a longer-term perspective.
However, decarbonising the economy and the development of Small
Modular Nuclear Reactors (SMRs) has the potential to change the
economics of nuclear power.
For a broader discussion of the economics of nuclear power, refer to Professor Owen's
chapter.
Construction and Nuclear Power
Historically, the nuclear industry (particularly in the US where
there has not been a standard design for nuclear power plants) has
been plagued by delayed construction schedules. Since about
two-thirds of the costs of generating electricity from a nuclear
power plant are accounted for by fixed costs arising from the
construction process, this is a significant issue in deploying
nuclear power.
Different countries have different approval processes,
regulatory regimes and political systems, all of which impact on
risk from the investors viewpoint. Construction delays, for
example, can significantly increase interest payments during
construction. Thomas (2005) reports that: "Forecasts of
construction costs have been notoriously inaccurate, frequently
being a serious underestimate of actual costs and - counter to
experience with most technologies where so-called 'learning', scale
economies, and technical progress have resulted in reductions in
the real cost of successive generations of technology - real
construction costs have not fallen and have tended to increase
through time." This lack of scale economies is not surprising given
the lack of orders for new generation reactors.
The challenges associated with constructing nuclear power plants
in liberalised economies is why, of the 62 reactors being developed
as of September 2011, 26 are being built in China, 10 in Russia,
six in India, five in South Korea and just three in OECD
countries.
For a more comprehensive discussion of the construction
challenges of nuclear power refer
to Professor Owen's chapter.
Nuclear renaissances in command and
control economies
The construction risks (link to appropriate CEDA
Snapshot) and the cost of capital are such that the nuclear
renaissance is likely to occur in command and control economies
such as China and Russia rather than liberalised economies.
Most nuclear plants currently operating in OECD countries were
built in an era when the power generation sector was a regulated
monopoly, which meant the cost of capital was relatively low, as it
was backed by government guarantee. In addition, any increase in
costs during construction could be clawed back from consumers in
the form of higher prices arising from the full cost recovery
nature of the sector pricing regime. (This meant there was little
investment risk for the builder of the nuclear power plant). Refer to Professor Owen's chapter.
Although the political will to expand nuclear capacity appears to
be present in many OECD countries, privately-owned electric
utilities do not appear to be in a position to comfortably support
the expansion of nuclear power. In contrast, state-owned power
companies in China, India, South Korea, and Russia have aggressive
nuclear expansion plans in place. As a consequence, of the 62
nuclear reactors described as being "under construction" worldwide
as of September 2011, there were 26 in China, 10 in Russia, six in
India, five in South Korea and just three in OECD countries.
The opportunities
associated with Small Modular Nuclear Reactors
In the past it may have been politically and economically
expedient to ignore nuclear power. However, the developments in
Small Modular Nuclear Reactors (SMRs) may make it very appropriate
for Australia's energy needs while future generations of nuclear
power reactors may provide incredible sources of clean energy with
high levels of safety. SMRs represent a new stage in nuclear
reactor design and have the capacity to provide an economically
competitive method of electrical power generation.
Historically nuclear power plants have been built larger and
larger. This trend was an attempt to obtain economies of scale in
deployment to overcome the high fixed construction costs. As a
consequence, modern nuclear power plants incurred substantial
financial costs and required large, well connected electricity
grids. There were limited options for deployment of such energy
generators in Australia.
The possible uses for SMRs in Australia include powering
Australian Defence Force sites, remote mining locations, large
industrial sites requiring reliable, competitive cost electricity
or process heat supplies, desalination plants, water treatment
plants, recycling schemes or irrigation systems and baseload
electricity supply for small grid systems.
A major advantage of SMRs is their passive safety. No electrical
supplies or pumps are required to cool the reactor, as this is
achieved by natural convection and gravity coolant feed. This
feature ensures the reactor will remain safe under severe accident
conditions. This also reduces the capital and maintenance costs
compared to large power reactors and fundamentally changes the
economic equation in favour of SMR nuclear power generation.
For a broader discussion of SMRs, refer
to Irwin's chapter.
The economic opportunities in the
nuclear fuel cycle
There is a substantial opportunity for Australia to play a more
fundamental role in the global nuclear fuel cycle. Australia's twin
stabilities of political and geographic systems make it uniquely
placed to hold nuclear waste material. This would not be a
global dumping ground but a sophisticated storage facility of
relatively little material. Furthermore, technological developments
in nuclear reactors may result in future generators using the waste
products of current reactors as fuel.
So the economic opportunity for Australia is to sell uranium,
then be paid for its storage and, eventually, be able to sell
today's waste product as a fuel source for the next generation of
reactors. This could be a lucrative industry built on world‑leading
technology developed in Australia. It would also make a positive
contribution to reducing the possibility of nuclear weapons
proliferation and a major contribution to global mitigation of
carbon emissions.
For a more comprehensive discussion of the economic
opportunities in the nuclear fuel cycle refer to
Dr Quirk's chapter.
Australia's Energy Options
Australia's Nuclear Options is part of CEDAs Australia's Energy
Options research.
The next two policy perspectives and release dates are as
follows:
- Renewables and efficiency, released 11 April
2012.
- Research and Innovation, released July 2012.
Members: Download a pdf copy here.
Non-Members: Purchase the report here.