1. Preamble
1. Nuclear electricity generation has long been a very
controversial industry and different countries have adopted widely
different policies in their approach to the subject. This report
is not intended to be for or against nuclear power, but to place
it in context within the wider debate involving all generation of
power and all use of fuels to provide energy.
2. The Parliamentary Assembly has already agreed that we must
aim to increase sustainable energy sources (see, for example,
Resolution 1435 (2005) on energy systems and the environment) and more recently has
examined the problems of disposing of nuclear waste (see
Resolution 1588 (2007) on radioactive waste and protection of the environment).
Both of these reports question the oft-quoted belief that nuclear
energy is “sustainable”. It is not: known resources of uranium are
finite and at best only available in the medium term, less in fact
than the known resources of coal, but rather more than oil and gas.
3. If the problem of global warming is to be successfully challenged,
then certainly in the short to medium term nuclear power could be
of great benefit, but there are some difficult problems. If we were
to see a large expansion of nuclear power then obviously the medium
term availability of uranium would become of shorter duration and
the problem of disposal of nuclear waste would become greater.
4. Consideration also has to be given to the advances being made
in carbon sequestration from the burning of fossil fuels. If these
advances become a total success then fossil fuel burning could become
at least as attractive as nuclear power.
5. An often overlooked fact involving nuclear power is the immense
amount of resources that has been invested in the research and development
of the industry. If but a fraction of this investment had been used
to advance the clean burning of fossil fuels and genuine sustainable
renewable energy resources, the whole scene would be very different
indeed.
6. I would like to pay tribute to my former Russian colleague
on the Environment Committee, Mr Grachev, who had almost completed
his report on this subject when he sadly retired from his membership
of the Council of Europe Parliamentary Assembly and it was decided
that your rapporteur would continue to complete and present the
report.
7. Mr Grachev was a much firmer advocate of nuclear power than
your present rapporteur, but the text of his original thoughts remains
unaltered.
8. Undoubtedly nuclear power has an important role to play in
mitigating the effects of climate change, but it falls far short
of a complete answer and must not be used as a smokescreen to dilute
the paramount effort to develop to the full all forms of renewable
energies, which will be needed to sustain the human race when all sources
of nuclear fuel and fossil fuel are gone, a scenario which is much
closer than many realise.
2. Introduction
9. The international community has to find effective
solutions to three interrelated tasks – energy security, economic
growth and environmental protection. Fair, competitive responses
to global energy challenges based on market economy principles will
help to prevent potentially destructive effects on production, supplies
and transit of energy resources and establish a solid basis for
the dynamic and sustainable long-term development of our civilisation.
10. Over the next thirty to fifty years nuclear energy will make
a significant contribution to resolving the problem of energy security
as a basis for sustainable development.
11. Nuclear energy is the most feasible, technologically proven,
environmentally acceptable and competitive alternative to hydrocarbon
energy. We believe that developing nuclear energy is a move in the
right direction.
12. Nuclear energy is viewed as an attractive option because of
certain competitive advantages, such as the least dependency on
fuel prices in comparison with other sources of energy, insignificant
volume of energy cargo transportation, detailed consideration of
nuclear and environmental safety matters, environmental protection
and the absence of greenhouse gas emissions or adverse effects on
climate.
13. The main prerequisites for widespread development of nuclear
energy are enforcing the nuclear non-proliferation regime, ensuring
security and safety of nuclear materials and further reducing the
different risks posed by its development.
14. Nuclear energy use can become a framework for establishing
an energy system ensuring sustainable, environmentally safe, cost-effective
and socially acceptable development and improvement in all fields
of human activity in the 21st century.
15. Its development will contribute to global energy security,
which will be possible only within a solid framework of international
co-operation.
16. At the same time, it has to be acknowledged that individual
solutions are no longer appropriate. In an increasingly global world,
only those who realise this fact will be capable of effective action.
17. To properly respond to the new challenges and exploit new
opportunities, the world nuclear energy industry should consolidate
its efforts. The different players should be systematically involved
in the international nuclear fuel cycle, pooling and making efficient
use of competitive advantages.
18. Further internationalisation of the nuclear fuel cycle to
ensure stable access to its products and services for the countries
concerned, while strictly complying with and strengthening the international
nuclear non-proliferation regime, is a strategic thrust for nuclear
energy.
19. The tasks facing Russia and the international community are
of a truly global nature. That means that sustainable, safeguarded
and safe development of nuclear energy can be achieved only through
joint bilateral and multilateral efforts.
20. Russia, as one of the world’s major suppliers of uranium-related
products and services, is fully open to and prepared for such co-operation.
3. Global energy issues
and sustainable development
21. In recent years, energy has become highly topical
all over the world. Today's world is changing fast in terms of both
newly emerging countries with rapidly developing economies and the
growing energy consumption of developed countries.
22. Growing tension on the energy markets in recent years is not
a temporary phenomenon. The world’s developed and developing countries
have aligned themselves in terms of per capita energy consumption.
23. At the same time the economy cannot survive without an adequate
energy supply, regardless of the country’s political system or its
level of development, and this applies equally to centrally planned
and market economies and to developed and developing countries.
24. Energy supply has come to the fore. Energy resources are critical
for improving living standards and expanding opportunities for people
in both developed and developing countries of the world.
25. Assuming that the existing consumption level in developed
countries will attain a balance, total energy production has to
increase at least threefold, and that is without taking world population
growth into consideration.
26. Thus, ensuring efficient, solid and environmentally safe energy
supplies at prices corresponding to the fundamental principles of
the market economy is a major challenge for humankind.
4. Principles of ensuring
global energy security
27. The tasks and principles of global energy security
include the following:
- openness,
transparency, stability, efficiency and competitiveness of markets
with regard to production and supplies as a key to ensuring global
energy security;
- establishing transparent, fair, stable and efficient legal
frameworks and legislative and regulatory systems;
- encouraging investment in the energy sector;
- improving energy efficiency and energy saving through
national and international initiatives;
- diversification of energy, geographical and industry markets;
- ensuring security of energy infrastructure;
- developing and introducing innovative energy-efficient
technologies;
- environmental responsibility in development and use of
energy resources, introduction and exchange of environmentally safe
technologies contributing to resolving the issue of climate change
and sustainable development;
- joint actions to mitigate the consequences of energy emergencies;
- resolving energy problems of the poorest population groups
in developing countries.
28. Many of these tasks which must be solved if global energy
security is to be ensured and strengthened were touched upon by
the G8 leaders in their St Petersburg summit declaration in 2006.
4.1. Improving transparency,
predictability and stability of global energy markets
29. The presence of free, competitive and open markets
is vital to an efficient global energy system as a key prerequisite
for sustainable development.
30. Transparency and predictability of energy policy and regulatory
regimes in each state contribute greatly to shaping efficient energy
markets.
31. Expanding dialogue between energy-producing and energy-consuming
countries can promote transparency, predictability and stability
of global energy markets.
32. The smooth functioning of world energy markets also requires
regular and timely exchange of accurate and credible information.
4.2. Improving the investment
climate in the energy sector
33. To ensure adequate energy supplies on a global scale,
several trillion US dollars should be invested in the energy sector
by 2030, with a considerable part of that amount allocated to satisfy
the needs of developing countries.
34. Conditions should be created and maintained to attract investment
in the energy sector by establishing competitive, open, fair and
transparent markets.
35. When making decisions on investment, great importance is attached
to the energy and environmental policy of a given state, and predictable
regulatory regimes in energy-producing, energy-consuming and energy-transiting
countries should therefore be promoted. This should include the
adoption of stable legislation based on the principles of the market
economy, investment governance and forecasting of medium- and long-term demand
for energy resources, the establishment of clear and consistent
taxation systems and the removal of excessive administrative barriers.
36. Attracting investments in all stages of the energy cycle can
make it easier to:
- introduce
innovative energy-efficient technologies;
- encourage wider use of renewable and alternative sources
of energy, primarily nuclear energy;
- introduce and expand use of more environment-friendly
and efficient technologies and methods, including in nuclear energy;
- develop efficient generation capacities in the field of
electric power production, including the development of nuclear
energy as one of the priorities;
- expand and improve efficiency, security and safety of
power networks, as well as possibly linking them up with energy
systems of other states, including developing countries.
37. Capital flow to energy production should be facilitated, including
for building new, more efficient installations and upgrading the
existing power plants (including nuclear power plants), to ensure
wider use of renewable energy sources.
38. Supplying properly qualified human resources for the energy
sector in the long term is critical to ensure energy security.
39. Adequate measures are required, therefore, to ensure proper
training of energy sector employees, including in the field of new
and innovative energy sources and technologies necessary to ensure
long-term energy security. The training of highly qualified personnel
for nuclear energy is especially important.
4.3. Improving energy
efficiency and energy saving
40. Saving energy resources plays an important role in
strengthening energy security. It is often a more cost-efficient
and environmentally responsible means of meeting the growing demand
for energy.
41. Energy efficiency and energy saving are among the most efficient
solutions to the problem of reducing greenhouse gas emissions.
42. In all development scenarios, energy saving, that is, making
energy consumption more efficient, is a priority activity achieving
maximum impact in the shortest time in resolving the climate change
issue. Expanding the use of nuclear energy can make a decisive contribution
here.
4.4. Energy diversification
43. Energy diversification is one of the most effective
instruments for reducing risks in the field of global energy security.
44. Developing low-carbon and alternative energy, making wider
use of renewable energy resources and introducing innovative technologies
in all energy sector industries can help reduce risks in global
energy security.
45. Nuclear energy has a special role to play in diversifying
energy sources, being the most feasible, technically proven, environmentally
acceptable and competitive alternative to carbon energy.
46. Nuclear energy is viewed as an attractive option because of
such competitive advantages as the least dependency on fuel prices
in comparison with other sources of energy, insignificant volume
of energy cargo transportation, detailed consideration of nuclear
and environmental safety matters and environmental protection.
4.5. Innovative energy
technologies
47. At the G8 summit held in 2007 in Heiligendamm, the
G8 leaders noted that: “Innovation is one of the crucial drivers
of economic growth in our countries. We therefore agreed to take
action to promote innovation as well as research and development.”
48. The arrival of innovative technologies on the market will
contribute to improving energy sector efficiency and strengthening
global energy security. These new initiatives include developing
potentially valuable technologies, including those linked to the
construction of improved power circuits, superconductivity and nanotechnologies
(including biological nanotechnologies); conducting research and
development in the field of fusion energy within the International
Thermonuclear Experimental Reactor (ITER) project; and implementation of
the IAEA International Project on Innovative Nuclear Reactors and
Fuel Cycles (INPRO).
49. Of all innovative energy technologies, nuclear energy is the
most feasible option, which, thanks to scientific and technical
advances in the field and the developed infrastructure, can take
the lead in energy production in the 21st century and ensure sustainable
human development.
4.6. Resolving the issues
of climate change and sustainable development
50. Sustainable development implies an environmentally
responsible approach to development and use of energy resources.
51. The entire international community has acknowledged that the
climate change issue must be resolved.
52. The Kyoto Protocol, the first international instrument applying
market principles to environmental protection, is an effective mechanism
promoting the reduction of greenhouse gas emissions and efficiently resolving
the issue of climate change.
53. Nuclear energy has a highly significant role in attaining
the goals of the Kyoto Protocol and the United Nations Framework
Convention on Climate Change (UNFCCC). The advantage of nuclear
energy is that it contributes the least to the “greenhouse effect”.
It is estimated that a nuclear power plant produces the lowest volume
of greenhouse gases per unit of energy compared with all types of
energy used at present or to be used in the future. Energy production
in nuclear power plants can enable humankind to cut greenhouse gas emissions
and significantly reduce their impact on the atmosphere, while large-scale
introduction of nuclear energy or the even more efficient new generation
of energy based on using energy of the deep structure of matter
will enable us to resolve the issue of climate change resulting
from human activity.
4.7. Reducing energy
poverty
54. It is impossible to drastically reduce poverty in
general without resolving the issue of energy poverty. If energy
poverty remains it is also not possible to support health care services,
supply people with safe drinking water, improve sanitation, make
agriculture more efficient, increase food production or create employment
by attracting investment in the enterprises of developing countries.
55. There appears to be a need for expanding access to energy
resources for the poorest population groups and improving energy
efficiency in developing countries.
56. Programmes of assistance to the developing countries should
be aimed at improving their policies and regulation systems in order
to attract private capital. International financial institutions
should help resolve these problems.
57. Nuclear energy can play an important role in reducing poverty
and ensuring long-term energy sustainability in developing countries.
At the same time, the development and use of nuclear energy should include
the development of energy infrastructure and personnel training.
5. Factors contributing
to reducing the role of conventional energy
58. A number of countries (for example, Germany, the
United States, France and Japan) have chosen to ensure energy security
by reducing dependency on non-renewable sources of energy – imported
oil and natural gas – through developing alternative electrical
energy sources, primarily nuclear energy.
59. This is not an arbitrary choice. Several years ago most experts
believed that oil would remain the main source of energy indefinitely
but they have now changed their minds. According to some estimates,
oil will remain the dominant source of energy for thirty years at
the most, for several reasons.
60. Firstly, oil prices are high and fluctuate. In 2005 world
oil prices rose by 42% as compared to 2004, while the average European
imported natural gas price increased by 48%. At the same time, the
share of fuel in the structure of goods has become highly significant.
61. However, from a strategic point of view, prices are not the
main reason. A more important factor is that, as the number of energy
consumers grows, especially in countries like India and China, a
shortage of oil will become inevitable.
62. It is not possible to constantly step up extraction either.
The oil reserves available are limited, and not only because the
volume of the subsoil is limited but also for a number of other
reasons. There is also an energy limitation, because the extraction
of oil which is difficult to access may require more energy than
it will generate. In this case cost becomes a secondary parameter.
63. Another source of energy is natural gas, which is also a valuable
raw material for many other industries. Dmitry Mendeleyev said that
burning natural gas is almost the same as using banknotes as fuel.
Nevertheless, we still do it.
64. The third important source of energy is coal. In Russia, for
example, coal is the source of about 18% of all the energy produced.
There is enough coal for another three hundred years, but the use
of coal is restricted by environmental regulations.
65. There is growing concern over atmospheric pollution which
calls for urgent solutions.
66. In addition, there are problems relating to transportation
infrastructure, which may prove inadequate to transport the growing
volumes of conventional energy as energy consumption increases.
67. All this means that ensuring efficient, stable and environmentally
safe energy at prices reflecting the fundamental principles of the
market economy is a challenge for our countries and humankind in
general, requiring solutions to a number of serious interrelated
issues, such as:
- growing demand
for energy resources (it is estimated that by 2030 demand will increase
by more than half, with 80% of it met by fossil fuels, reserves
of which are limited);
- growing dependency of many countries on imported fuel;
- the need for enormous investment in all stages of the
energy production cycle;
- the need to protect the environment and resolve the issue
of climate change;
- political instability, natural disasters and other threats.
68. As all these issues are of a global nature, partnership should
be forged between all the parties concerned in order to strengthen
global energy security.
6. The role of nuclear
energy in sustainable development
69. Nuclear energy plays a special part in solving the
problems of energy resources, ensuring sustainable development and
energy security. This has already been recognised by Russia and
many other countries in the world.
70. Nuclear energy should be environmentally safe, cost-effective,
stable in terms of non-proliferation and should be underpinned by
a reliable system ensuring security and safety of nuclear materials
and facilities.
71. It will be impossible to reach a sustainable fuel and energy
balance within the next thirty to fifty years without large-scale
development of nuclear energy.
72. Today, nuclear energy is the only feasible and available source
of energy valuable in terms of preserving the balance between world
energy production and the growing demand for electric power. Nuclear
energy is also attractive in terms of reducing atmospheric pollution
and, consequently, resolving the problem of climate change.
73. One key point is that thirty to forty years ago, when the
nuclear energy industry was in its infancy, it was merely an aspect
of military nuclear programmes. Large-scale civilian nuclear programmes
were implemented mostly in countries where major military nuclear
programmes existed.
74. Today, given increasing prices for hydrocarbons and the boom
in energy consumption, nuclear energy has gained its own value.
6.1. Prerequisites for
nuclear energy development
75. The situation in the world is very different now
and characterised by two important features:
- Nuclear energy development has become global. Whereas
in the past only certain countries developed nuclear technologies,
today the process has become truly global. More and more countries
find it right and reasonable to have access to cheap and efficient
nuclear energy.
- Taking into consideration that in the area of nuclear
energy almost no country in the world can act absolutely independently,
the nuclear energy market is one where everyone depends on everybody else.
76. Such mutual dependence and the global nature of the market
call for a serious joint review of the rules governing this market.
Given its tight links with military programmes, the market remained
closed and isolated for quite a long time. Today, it has become
global and more open, but a number of outdated and obsolete rules were
retained.
77. In terms of ensuring the safety and security of nuclear energy,
the most important factor is creating open, transparent and equal
conditions for countries to access the market of goods and services
offered by the world nuclear energy sphere.
78. At the same time, it should be understood that improving public
opinion regarding civilian nuclear programmes and relevant decisions
by the leaders of states is a necessary condition but not the only
one.
79. With no facilities and no proper set-up for the nuclear fuel
cycle, there will be no nuclear renaissance. And there are still
a number of tasks to be resolved in this area.
80. If new nuclear power plants are commissioned throughout the
world, there will be enormous pressure on the first stage of the
nuclear fuel cycle, whose major phases include the extraction of
natural uranium, its enrichment and fuel production. Production
will have to be expanded. Only if this development goes hand in hand
with the development of generating facilities can we expect peaceful
nuclear programmes to play the leading role in supplying humankind
with energy.
81. A further important task to be resolved is the management
of spent nuclear fuel and radioactive waste.
6.2. Nuclear renaissance
82. Today, nuclear energy is an efficient and stable
source of about 17% of electric power produced worldwide. At the
same time, rapid economic growth in certain regions and countries
has already made it necessary to plan ahead for new energy capabilities
and development of the relevant production and energy infrastructure.
According to IAEA estimates, between 30% and 80% of increased energy
capacity in Asia, for example, can be achieved by building nuclear
power plants.
83. With this in mind, the fact that nuclear energy development
has been actively discussed worldwide, which is a true nuclear renaissance,
seems reasonable and logical. Besides this, a nuclear renaissance
is becoming increasingly feasible.
84. Considering that the experience of running nuclear power plants
in recent years has shown that this kind of energy is efficient
and safe, it is only logical that many countries have already adopted
programmes for more widespread nuclear power plant construction.
85. Countries like Russia, China, India, the Republic of Korea,
the United States and Japan have clearly stated their intentions
as to nuclear power plant construction. For example, by 2030 nuclear
energy may become the major source of energy in Japan, supplying
over 40% of the country's energy.
86. Decisions to develop civilian nuclear power programmes have
been taken in countries which have never developed and do not intend
to develop the military component of nuclear programmes. Turkey
has decided to build a nuclear power plant on the Black Sea coast.
Construction is to begin in 2007 and three power plants will have
been completed by 2015. The Australian Prime Minister has supported
nuclear energy development in his country, and experts believe that
nuclear electric power may already be generated in Australia in
ten years' time. Construction of a nuclear power plant in Poland
is under consideration. Asia-Pacific countries also plan to develop
nuclear energy.
87. In a number of other countries, such as Great Britain, Italy
and even Germany, well-known for its anti-nuclear policy, there
is growing discussion of the future role of civilian nuclear energy
as a key component of the energy balance.
88. When evaluating the quantitative indices of nuclear renaissance
American experts concluded that aggregate world nuclear power plant
capacity will increase from 371 GWt in 2005 to 438 GWt in 2030,
which is a very significant increase, especially since the commissioning
of new nuclear power facilities has been a fairly rare occurrence
in the last twenty years.
6.3. Nuclear energy
development in Russia
89. Russia is one of the many countries sharing this
opinion.
90. In that country opting for national nuclear energy is not
only a political decision imposed by circumstances but it is backed
by a specific programme of action aimed at creating the full spectrum
of necessary conditions. Nuclear energy is developed on the basis
of the necessary legal, financial and administrative framework.
91. The federal targeted programme entitled “Development of Russia's
Nuclear Energy Production Complex in 2007-2010 and subsequently
up to 2015” is a public-private partnership for building new nuclear
energy facilities. Government support at this stage does not imply
that Russian nuclear power plants are not competitive in comparison
to other types of energy but acts as a compensation mechanism until
market relations are developed. The Russian Government has decided
that market relations should be introduced into the electric power
sector after 2011.
92. In July 2007 the Russian Federation Government approved the
federal targeted programme “Ensuring Nuclear and Radiation Security
for 2008 and up to 2015”, which provides for state funding for management
of spent nuclear fuel and radioactive waste and decommissioning,
problems that remained unsolved in the previous stages of nuclear
energy development.
93. A federal law has been adopted, providing for restructuring
of the industry and a transition to market relations in its civilian
sector. For the first time, legal entities have been granted the
right to own nuclear materials and facilities, while state-owned
enterprises in this sphere are to be transformed into joint stock companies.
94. This summer saw the founding of AtomEnergoProm, a holding
comprising major civilian nuclear energy enterprises. This open
joint stock company is a nuclear energy production complex which
aims to concentrate the resources needed for the tasks ahead.
95. Today our minimum target is to ensure that at least 16% of
energy is produced by nuclear power plants and the weighted average
target is the index set by the energy strategy (22%), while a 25-30%
share is called for in real terms, this being the average index
of the developed countries.
96. Long-term technology policy envisages the development of a
model design “Nuclear Power Plant 2006” based on a WWER reactor
and the gradual introduction by 2030 of new fourth-generation fast
neutron reactor nuclear energy technology, a complete nuclear fuel
cycle and uranium-plutonium fuel, which should remove limitations
with regard to raw materials of fuel for the foreseeable future.
6.4. Complying with
the nuclear non-proliferation regime
97. Large-scale nuclear energy development across the
world is closely linked with the access of more and more states
to nuclear technologies, materials and equipment. This means that
the international community faces issues related to nuclear non-proliferation
and nuclear and environmental safety, as well as ensuring the security
and safety of nuclear materials, the economic competitiveness of
nuclear energy and a reduction of related risks.
98. In these circumstances, the states with developed nuclear
industries should pool their efforts in order to provide assistance
to states interested in developing nuclear energy.
99. In the current situation, given the new challenges and threats
facing the world community, the balance between developing world
nuclear energy and complying with the nuclear non-proliferation
regime should be ensured.
100. Maintaining that balance is not an easy task. As already pointed
out, more and more countries are opting for nuclear energy development,
which will inevitably entail uranium enrichment and the need to
process spent nuclear fuel. Building the nuclear fuel cycle facilities
required is expensive. Another important task is IAEA control. Furthermore,
there is always a risk that civilian technologies might be used
for military purposes.
101. In this context, a problem arises of how, on the one hand,
to guarantee access to nuclear fuel and services relating to spent
nuclear fuel management for the countries concerned and, on the
other hand, to restrict the spread of nuclear technologies and the
construction of new nuclear facilities in different parts of the world
and to avoid new risks for the nuclear non-proliferation regime.
102. It is not possible for technical, political and ethical reasons
to prohibit access to cheap and efficient nuclear energy for those
countries.
103. This is impossible when access to cheap and efficient energy
resources is a key prerequisite for development.
104. The task facing the world community is to develop new systems
that would guarantee the right of any country in the world to use
nuclear energy for civilian purposes while ensuring strict compliance
with the nuclear non-proliferation regime.
7. Nuclear fuel cycle
initiatives
105. We recognise that this is an extremely complex matter
and international co-operation is therefore especially important
in seeking solutions to the aforementioned problems.
106. In recent years, a number of initiatives have been launched
with regard to the nuclear fuel cycle, including the following:
- the initiative of Vladimir Putin,
President of the Russian Federation, on energy support for sustainable human
development, resolving the issues of non-proliferation of nuclear
weapons and improving the environmental situation on the planet,
announced during the Millennium Summit in 2000, and that of the United
States (IAEA INPRO project);
- the International Forum Generation-IV project;
- IAEA activities geared to identifying a mechanism guaranteeing
fuel supply for nuclear power plants in the countries developing
nuclear energy;
- bilateral Russian-American co-operation in civilian nuclear
energy;
- initiative of the President of the Russian Federation
of 25 January 2006 on developing a global nuclear energy infrastructure
(International Uranium Enrichment Centre – IUEC);
- the US Initiative for Global Nuclear Energy Partnership
(GNEP);
- Joint Statement by the presidents of the United States
and Russia on nuclear energy and non-proliferation joint actions,
of 3 July 2007.
107. These and other initiatives are all important, each having
its own advantages and limitations.
108. The initiative of the Russian Federation President of 25 January
2006 on developing a global nuclear energy infrastructure is one
of the mechanisms aimed at allowing equal access to nuclear energy
for all the countries concerned while ensuring compliance with the
requirements of the nuclear non-proliferation regime.
109. The initiative is aimed at further developing nuclear energy
as a basic component for ensuring global energy security. The Russian
initiative could provide a feasible opportunity to develop nuclear
energy across the world swiftly and safely taking due account of
the need to ensure non-proliferation of the most sensitive nuclear
technologies for uranium enrichment and spent nuclear fuel processing.
110. As with its national nuclear energy development programme,
Russia's approach to these issues involves gradual, phased supply
of resources and specific progress – not promises and attractive
but unworkable models, but specific yet small-scale actions proven
in practice.
111. Uranium enrichment technology is the most sensitive part of
the first stage of the nuclear fuel cycle in terms of proliferation.
Therefore, a solution is required that would curb the tendency of
countries striving to develop nuclear energy to independently develop
enrichment technologies. This solution should meet at least three
requirements: it should guarantee a reliable supply of nuclear fuel,
be commercially attractive and ensure compliance with the nuclear
non-proliferation regime.
112. Since uranium enrichment is a necessary technological process
in producing nuclear fuel for power plants, and at the same time
the most sensitive part of the nuclear fuel cycle in terms of proliferation,
the first IUEC has been set up in Angarsk, in the Russian Federation.
113. In practice, the centre guarantees states access to uranium
enrichment capabilities to meet nuclear fuel needs without creating
their own nuclear fuel cycle, which consumes a great deal of time
and resources.
114. The sponsors of the centre, under an inter-governmental agreement
of 10 May 2007, are the Russian Federation and the Republic of Kazakhstan.
The centre's main task is to provide guaranteed access to the uranium
enrichment capacities of the Angarsk Electrochemical Plant Federal
State Unitary Enterprise with a view to providing uranium enrichment
services so that fuel for nuclear energy may be produced.
115. To ensure that the centre is run on market principles, it
was set up under Russian Federation laws as an open joint stock
company, making the initiative more financially attractive, since
participating organisations will not only have access to uranium
enrichment services to satisfy their needs but also receive dividends
from the centre's activities.
116. Third party states may join the centre at any time, with no
political conditions attached.
117. Russia has been working constructively with the IAEA to identify
specific parameters for the participation of the agency in the centre's
activities.
118. Since the materials of the centre should be covered by IAEA
safeguards, an unprecedented step has been taken to enable the agency
to monitor activities at the Angarsk Electrochemical Plant. This
is the underlying basis for the centre and the plant has been excluded
from the list of especially sensitive facilities of the Russian
Federation and included in the list of nuclear fuel cycle facilities
covered by IAEA safeguards. The necessary procedures to include
the centre in this list are currently being completed.
119. The centre could very well become involved in the IAEA project
on guaranteed supplies. The centre can guarantee uranium enrichment
services with the use of time-tested, technology-intensive and competitive technology
of isotope enrichment, as well as contribute to establishing the
system of guaranteed supplies of nuclear fuel to satisfy nuclear
energy needs.
120. In response to the initiative of Mohamed ElBaradei, IAEA Director-General,
on a nuclear material bank under the auspices of the IAEA, the Russian
Federation intends to create an enriched uranium reserve whose storage
is to be entrusted to the centre. Materials from this reserve will
be supplied upon IAEA request in force majeure circumstances
(when both enricher and the market deny uranium supplies for political
reasons) to any state developing a civilian nuclear energy programme
on condition that it complies with its non-proliferation commitments.
121. It is believed that the Russian proposal to create an enriched
uranium reserve at the centre as a branch of the IAEA nuclear fuel
bank will enable the implementation in practice of the new mechanism
provided for by the guaranteed supplies concept and will be a step
towards creating a world infrastructure for nuclear energy of the
future.
122. President Putin's initiative is based on the understanding
that there should be numerous international centres around the world.
Russia is not striving for a monopoly; it is just trying to provide
an example by setting the centre up on its territory.
123. On 3 July 2007 the presidents of Russia and the United States
adopted a Joint Russian-American Declaration on “nuclear energy
and non-proliferation joint actions”.
124. This declaration reflects our common approach regarding a
new form of joint action to support the expanded use of nuclear
energy and implementation of earlier initiatives in the field of
multilateral approaches to the nuclear fuel cycle.
125. To attain the goals set out in the declaration, activities
are proposed in fields such as supporting the supply of modern nuclear
reactors, promoting the development of infrastructure necessary
for nuclear energy and supporting access to financial resources
for the construction of nuclear power plants, including loans from international
credit organisations, supporting guaranteed supplies of nuclear
fuel and providing assistance in managing spent nuclear fuel.
126. It should be stressed once again that the task is to give
all states intending to use and develop nuclear energy an opportunity
to freely choose their nuclear fuel cycle strategy, including the
opportunity to benefit from nuclear energy without creating their
own nuclear fuel cycle elements which would be costly and unsafe
in terms of nuclear safety and nuclear non-proliferation.
127. Furthermore, Russia supports other nuclear fuel cycle-related
initiatives, including the initiative by the US President on the
GNEP and the proposals made by the group of major suppliers of enriched
uranium within the guaranteed supplies scheme.
8. Innovations in
nuclear energy
128. Of all innovative energy technologies, nuclear energy
is the most feasible option and, thanks to scientific and technical
advances in the field and developed infrastructure, can take the
lead in energy production in the 21st century and ensure sustainable
human development.
129. At present, many nuclear energy countries are implementing
programmes aimed at creating an image of nuclear energy acceptable
for both producers and consumers, drawing up principles, requirements
and criteria for its creation and functioning in the future, and
specifying and launching the necessary research and development.
130. Innovative nuclear energy will be based on principles differing
from those typical for modern nuclear energy, which is based on
fuel supply, electricity generation and spent nuclear fuel management
technologies, each run as a separate and independent operation.
131. Innovative nuclear energy will bring together all these operations
within one technologically closed-loop fuel cycle, solving two major
problems: where fuel comes from and where nuclear waste goes.
132. What is the most feasible option for supplying energy for
the sustainable development of civilisation today?
133. The most energy-rich raw material known today is natural uranium.
The aggregate capacity of the world uranium reserve is ten times
greater than that of world reserves of hydrocarbons – coal, oil,
and natural gas together. However, modern nuclear energy technologies
involving thermal reactors make it possible to use only one uranium
isotope – U-235. Its natural uranium content, consisting of a number
of different isotopes, is as low as 0.7%. The content of another
component of this mix – U-238 – is 140 times higher, while almost
90% of it goes into enrichment facility refuse and another 10% into
spent nuclear fuel, which is often inaccurately referred to as nuclear
waste. In general, the thermal reactor-based system can extract
energy from only about 0.5% of all nuclei of natural uranium. If
this type of nuclear energy is intensively developed, the world
will run out of uranium very soon, in another fifty years.
134. One of the major advantages of nuclear energy raw material
is its renewability, thanks to the possibility of generating energy
and regenerated fuel using fast neutron reactors.
135. This technology is now ready for large-scale introduction,
and Russia is leading the field in this respect.
136. This is confirmed, in particular, by the successful functioning
of fast neutron sodium reactors BR-10, BOR-60, BN-350 and BN-600.
The latter has been operated for over twenty-five years at the Beloyarskaya Nuclear
Power Plant in the Urals, and it is the only commercial fast reactor
in the world. Another, more powerful reactor, BN-800, is now being
constructed there.
137. In fast reactors, both wholly natural uranium and accumulated
refuse of enrichment enterprises and nuclear waste of thermal reactors
will become fuel.
138. There are various development options: a fast reactor can
be constructed with a core that generates the same amount of fuel
which is subsequently burnt.
139. The system can also be geared to expanded fuel generation
in a special blanket around the core, which will produce more plutonium
than will be burnt. This excess plutonium can be used to launch
new fast reactors.
140. In addition, there is natural thorium, the world reserve of
which is several times greater than the world uranium reserve. Using
fast reactors this resource can also be easily integrated in innovative
nuclear energy.
141. Achieving these ambitious tasks will depend on numerous interrelated
factors. In addition to creating and developing basic elements of
a new technological platform for innovative nuclear energy, many
new industrial facilities should be constructed and new specialists
should be trained for them. A brand new nuclear energy system should
be deployed, involving a closed-loop fuel cycle that is safe, low-waste,
environment-friendly and sustainable in terms of nuclear weapon
proliferation.
142. All this requires time and considerable investment. Investing
incomes from oil and gas could boost the development of this energy
resource. As a result, in thirty to fifty years' time the world
could have a virtually inexhaustible source of energy for a historical
period of several thousand years.
8.1. IAEA International
Project on Innovative Nuclear Reactors and Fuel Cycles (INPRO)
143. International co-operation has been launched and
developed to devise principles, requirements and criteria for the
future creation and functioning of innovative nuclear energy.
144. At the Millennium Summit (6 September 2000, US) the President
of the Russian Federation, Vladimir Putin, proposed an initiative
on the sustainable development of humankind and radical means of
addressing the issues of non-proliferation of nuclear weapons and
the environmental protection of planet Earth.
145. The Russian initiative has been implemented through the IAEA
INPRO project which at present brings together 28 countries including
the leaders in world nuclear energy – the US, France, Japan and
the European Commission. Dynamically developing countries such as
China and India have played an active part in the project almost
since it was launched.
146. INPRO is aimed at developing innovative nuclear energy systems
and nuclear fuel cycles excluding the use of plutonium and highly
enriched uranium, as well as enrichment and processing technologies
sensitive in terms of proliferation of nuclear weapons.
147. The project has been widely supported worldwide, which is
reflected in the relevant IAEA General Conference and United Nations
General Assembly resolutions and the documents of the St Petersburg
G8 summit.
148. INPRO will enable nuclear energy to make an adequate contribution
to satisfying the growing demand for energy in the 21st century.
149. INPRO will also serve as the scientific and technical basis
needed to fulfil the tasks set out in the Russian President's initiative
on developing global infrastructure for nuclear energy (2006), alongside
the principles of the GNEP.
150. This international project will provide an opportunity to
unite all the participating countries concerned, including both
nuclear technology countries and nuclear technology users, in jointly
reviewing means of satisfying energy demand. It will also facilitate
implementation of international initiatives aimed at developing and
expanding the use of nuclear energy for civilian purposes in strict
compliance with the nuclear non-proliferation regime.
151. INPRO is seen to be a platform for joint identification of
the international and national measures required for devising and
deploying innovative nuclear energy systems and for the use of advanced
and economically competitive technologies, characterised by enhanced
safety and minimum risk of proliferation and negative effect on
the environment, in the innovative process.
152. Expanding the use of nuclear energy as a reliable source to
satisfy the growing energy demand in developing countries calls
for solutions for a number of tasks:
- devising common user requirements for nuclear technology
and requirements for infrastructure in the consuming country;
- supporting international co-operation in identifying and
implementing innovative solutions meeting the new requirements for
nuclear technology;
- promoting infrastructure development and personnel training;
- supporting regional approaches;
- control over and participation in creating international
nuclear fuel cycle centres;
- ensuring guaranteed supplies.
153. Innovations in nuclear energy at this stage of the development
and expansion of its use call for a responsible and structured approach.
154. Methodology could be developed to attain this goal, a kind
of international standard for systematic evaluation of nuclear energy
solutions and scenarios at the national, regional and global level,
taking into consideration all critical aspects of nuclear energy
development (safety, environmental friendliness, cost-effectiveness,
resistance to proliferation, etc.), as well as current achievements
and potentially valuable technological solutions.
155. Using methodology like this could make it easier, for example,
to forecast national and regional development of nuclear energy,
identify optimum options and potential difficulties and provide
countries with up-to-date recommendations on risk evaluation and
prevention.
8.2. International Thermonuclear
Experimental Reactor (ITER) project
156. Special attention should be focused on one innovative
nuclear system in particular, the International Thermonuclear Experimental
Reactor (ITER) project.
157. The significance of the ITER project can hardly be overestimated:
it is deservedly viewed as a real means of harnessing a new source
of energy for the benefit of all humankind:
- Thermonuclear energy is attractive because of the virtual
inexhaustibility of fuel resources and its environmental friendliness.
Thermonuclear reactor fuel (hydrogen isotopes) can be found in limitless quantities.
- Thermonuclear energy is safer than nuclear energy. It
does not pose a threat of Chernobyl-type accidents and leakages
of radioactive substances, as it is based on synthesis and not fission
and therefore cannot result in a chain reaction.
- The initial designs for a system involving magnetic plasma
confinement called Tokamak, which served as a basis for the ITER
project, were developed by Russian scientists. Tokamak (stands for
Toroidal-Shaped Envelope with Magnetic Coils) has been the only
survivor of the 114 thermonuclear reactor concepts proposed by physicists
around the world.
- The Tokamak concept was tested by the Kurchatov Institute
experts and was proclaimed a success. The achievements of Russian
scientists in the field of superconductors and original methods
of fine electron plasma heating also played a significant role in
the ITER project.
158. However, the design and technologies of thermonuclear power
plants are extremely complex. ITER will go down in history as an
ambitious global project implemented through the consolidated efforts
of the whole of civilisation. Its intellectual and financial scale
is even greater than that of the International Space Station. A constant
temperature of 150 million °C has to be maintained inside a thermonuclear
reactor (whereas the temperature inside the Sun is only 20 million °C).
It is under this plasma temperature that the hydrogen isotopes burn,
leaving no radioactive refuse. At the same time, the amount of energy
produced with a unit of thermonuclear fuel is 10 million times greater
than those produced through uranium nuclei fission in nuclear power
plants' reactors.
159. ITER is designed to overcome the final obstacle on the way
to creating the first thermonuclear power plant, which will resolve
the energy problems facing humankind.
160. Implementing innovative projects like INPRO and ITER could
provide the solutions needed to ensure global energy security and
sustainable human development.
9. Conclusions
161. Today, there is growing interest in nuclear energy
as a means of ensuring energy supplies for the world's sustainable
development. Developing nuclear energy will enable humankind to
resolve one of the most pressing global issues, the issue of climate
change. Innovative development of nuclear energy will allow it to be
regarded as a renewable energy source that can meet the growing
demands of humankind. At the same time, large-scale use of nuclear
energy in the 21st century will face not only system and technology
obstacles characteristic of modern nuclear energy, but also political,
infrastructure and economic restrictions.
162. Overcoming those obstacles and resolving the task of comprehensive
energy support for sustainable development is closely linked to
the construction of a world infrastructure for nuclear energy based
on a new innovative technological platform, including the establishment
of international centres providing nuclear fuel cycle services under
IAEA safeguards (uranium enrichment, managing spent nuclear fuel,
and personnel training).
163. Foundations for a global nuclear energy infrastructure cannot
be laid without broader international co-operation and active participation
of all the countries concerned.
Reporting committee: Committee
on the Environment, Agriculture and Local and Regional Affairs
Reference to committee: Doc. 11198, Reference 3333 of 16 April 2007
Draft resolution adopted
unanimously by the committee on 29 April 2009
Members of the committee:
Mr Alan Meale (Chairperson), Mrs Maria Manuela de Melo (1st Vice-Chairperson), Mr Juha Korkeaoja (2nd
Vice-Chairperson), Mr Cezar Florin Preda (3rd
Vice-Chairperson), Mr Remigijus Ačas, Mr Ruhi Açikgöz, Mr Artsruni Aghajanyan, Mr Miloš Aligrudić,
Mr Alejandro Alonso Nùñez (alternate: Mr Gabino Puche Rodriguez Acosta), Mr Gerolf
Annemans, Mr Miguel Arias Cañete (alternate: Mr Pedro María Azpiazu Uriarte), Mr Alexander
Babakov, Mrs Guðginnz S. Bjarnadóttir, Mr Ivan Brajović, Mrs Elvira Cortajarena Iturrioz, Mr Veleriu
Cosarciuc, Mr Vladimiro Crisafulli, Mr Taulant Dedja, Mr Hubert Deittert, Mr Karl Donabauer (alternate:
Mr Alexander van der Bellen),
Mr Miljenko Dorić, Mr Gianpaolo Dozzo, Mr Tomasz Dudziński, Mr József
Ékes, Mr Savo Erić, Mr Bill Etherington,
Mr Nigel Evans, Mr Joseph
Falzon, Mr Ivàn Farkas, Mr Relu Fenechiu (alternate: Mr Ionut-Marian Stroe), Ms Eva Garcia Pastor, Mr
Zahari Georgiev, Mr Peter Götz, Mr Rafael Huseynov,
Mr Jean Huss, Mr Fazail Ibrahimli,
Mr Ivan Ivanov, Mr Igor Ivanovski,
Mr Bjørn Jacobsen, Mrs Danuta Jazłowiecka,
Mr Stanisław Kalemba, Mr Guiorgui Kandelaki (alternate: Mr Paata Davitia), Mr Haluk Koç, Mr Dominique Le Mèner (alternate:
Mr Jean-François Le Grand), Mr
Anastosios Liaskos, Mr François Loncle (alternate: Mrs Maryvonne Blondin), Mr Aleksei Lotman, Mrs Kerstin Lundgren, Mr Theo Maissen, Mr Yevhen Marmazov, Mr Bernard Marquet, Mr José Mendes Bota, Mr Peter Mitterrer, Mr Pier Marino Mularoni, Mr Adrian Năstase, Mr Pasquale Nessa, Mr
Tomislav Nikolić, Mrs Carina Ohlsson (alternate: Mr Kent Olsson), Mr Joe O’Reilly, Mr Germinal
Peiro (alternate: Mr Alain Cousin), Mr
Ivan Popescu, Mr René Rouquet, Mrs Anta Rugāte, Mr Giacento
Russo, Mr Fidias Sarikas, Mr Leander Schädler,
Mr Herman Scheer, Mr Mykola Shershun,
Mr Hans Kristian Skibby, Mr Ladislav Skopal, Mr Rainder Steenblock, Mr Valerij Sudarenkov, Mr Vilmos Szabo, Mr
Vyacheslav Timchenko, Mr Bruno Tobback, Mr Nikolay Tulaev, Mr Tomas
Ulehla, Mr Mustafa Ünal,
Mr Henk van Gerven (alternate: Mr Paul Lempens),
Mr Peter Verlič (alternate: Mr Jakob Presečnik),
Mr Rudolf Vis, Mr Harm Evert
Waalkens, Mr Hansjörg Walter (alternate: Mrs Francine John-Calame), Mrs Roudoula Zissi
NB:The names of those
members present at the meeting are printed in bold
Secretariat to the committee: Mrs
Nollinger, Mr Torcătoriu and Mrs Karanjac