Nuclear proliferation: Difference between revisions

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As of 2022, countries with nuclear weapons have followed one or both of two paths in producing fissile materials for nuclear weapons: enrichment of uranium to very high fractions of U-235 (HEU), or extraction of fissile plutonium (Pu) from irradiated uranium nuclear reactor fuel. Both paths are technically challenging but achievable. The US forged the way on both paths during its World War II Manhattan Project. The fundamental aspects of both paths are well understood, but both are technically challenging. Even relatively poor countries can be successful if they have sufficient motivation, financial investment, and, in some cases, direct or illicit assistance from more technologically advanced countries.
{{subpages}}
=Section 1=
{{TOC|left}}
The International Atomic Energy Agency (IAEA) has a vigorous program to prevent additional countries from acquiring nuclear weapons. The Treaty on the Non-Proliferation of Nuclear Weapons (NPT) is the cornerstone arrangement under which strategic rivals can trust by independent international verification that their potential nuclear opponents  are not developing a nuclear weapons threat. The large expense of weapons programs makes it very unlikely that a country that knows its rivals are not so engaged would anyway start or maintain its own nuclear weapons program. With some notable and worrying exceptions, this has been largely successful.<br>
<onlyinclude>
'''Nuclear weapons proliferation''' is one of the four big issues that have held back worldwide deployment of peaceful nuclear power. This article will address the proliferation questions raised in [[Nuclear power reconsidered]].


=Section 2=
As of 2022, countries with nuclear weapons have followed one or both of two paths in producing fissile materials for nuclear weapons: enrichment of uranium to very high fractions of U-235, or extraction of fissile [[plutonium]] (Pu-239) from irradiated [[uranium]] [[nuclear reactor]] fuel. The US forged the way on both paths during its [[World War II]] [[Manhattan Project]]. The fundamental aspects of both paths are well understood, but both are technically challenging. Even relatively poor countries can be successful if they have sufficient motivation, financial investment, and, in some cases, direct or illicit assistance from more technologically advanced countries.
It is frequently claimed that building a civil nuclear power program produces a weapons proliferation risk. There is an overlap in the two distinct technologies, after all. And enriching uranium to levels needed by existing reactors (under 5%, or LEU) or advanced nuclear reactors (some near 20%, or high-assay LEU) is the same technology that can enrich uranium to very high levels. Enrichment levels and centrifuge configurations can presumably be monitored using remote cameras, on-site inspections, and installed instrumentation -- hence the value of international inspections by the IAEA.  Using commercial power reactors is an extremely ineffective, slow, expensive, easily detectable way to produce Pu for weapon use because refueling them is both time-consuming and detectable. That is why the US and other countries developed specialized Pu production reactors and/or uranium enrichment to produce fissile cores for nuclear weapons.<br>


=Section 3=
=The International Non-proliferation Regime=
While nuclear weapons proliferation is a matter of extreme importance, it is not apparent that it is a consequence of a country’s deployment of commercial nuclear reactors. Table 1 lists all the countries with operating commercial nuclear reactors (as of 2022) plus countries without commercial nuclear reactors but declared or known to be nuclear weapons states. There are 33 countries/entities with operating commercial nuclear reactors. Seven possess nuclear weapons, five of which developed commercial nuclear power after producing weapons. (North Korea does not operate power reactors, but does have nuclear weapons.) The Joint Comprehensive Plan of Action (The Iran Nuclear Deal) was based on the evidence that Iran’s new Bushehr Russian pressurized water reactors (VVERs) were not part of a weapons program, but that Iran’s uranium enrichment program and its uncompleted research reactor at Arak were.<br>
The [[International Atomic Energy Agency]] (IAEA) has a vigorous program to prevent additional countries from acquiring nuclear weapons. The [[Treaty on the Non-Proliferation of Nuclear Weapons]] (NPT) is the cornerstone arrangement under which strategic rivals can trust, by independent international verification, that their rivals are not developing a nuclear weapons threat. The large expense of weapons programs makes it very unlikely that a country would start its own nuclear weapons program, if it knows that its rivals are not so engaged. With some notable and worrying exceptions, this program has been largely successful.
 
=Paths to the Bomb=
It is frequently claimed that building a civil nuclear power program adds to the weapons proliferation risk. There is an overlap in the two distinct technologies, after all. To build a bomb, one needs Highly Enriched Uranium (HEU) or weapons-grade plutonium (Pu-239).
Existing reactors running on Low Enriched Uranium (LEU, under 5% U-235) or advanced reactors running on High Assay LEU (HALEU,up to 20% U-235) use the same technology that can enrich uranium to very high levels, but configured differently. Enrichment levels and centrifuge configurations can be monitored using remote cameras, on-site inspections, and installed instrumentation -- hence the value of international inspections by the IAEA.  Using commercial power reactors as a weapons plutonium source is an extremely ineffective, slow, expensive, and easily detectable way to produce Pu. Besides the nuclear physics issues, refueling pressurized water reactors is both time-consuming and obvious to outside observers. That is why the US and other countries developed specialized Pu production reactors and/or uranium enrichment to produce fissile cores for nuclear weapons.<br>
</onlyinclude>
=The Historical Record=
While nuclear weapons proliferation is a matter of extreme importance, it is not apparent that it is a consequence of a country’s deployment of commercial nuclear reactors. Table 1 lists the countries with both nuclear weapons and operating commercial reactors (as of 2022). There are 33 countries/entities with operating commercial nuclear reactors. Eight, possibly nine, possess nuclear weapons, two of which developed weapons after developing commercial nuclear power. North Korea has nuclear weapons, but no power reactors. Iran is pursuing nuclear weapons, and has power reactors. The Joint Comprehensive Plan of Action (The Iran Nuclear Deal) was based on evidence that Iran’s new Bushehr Russian pressurized water reactors (VVERs) were not part of a weapons program, but that Iran’s uranium enrichment program and its uncompleted research reactor at Arak were.


{| class="wikitable" bgcolor="#DDDDDD";
{| class="wikitable" bgcolor="#DDDDDD";
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!'''Comments'''&nbsp;
!'''Comments'''&nbsp;
|-
|-
| China || 1964 || 1991 || Enrichment
| China || 1964 || 1991 || Uranium enrichment
|-
|-
| France || 1960 || 1963 || UPGG Pu production reactor
| [[France]] || 1960 || 1963 || UPGG Pu production reactor
|-
|-
|India|| 1974 || 1969|| Pu production reactor
| [[India]] || 1974 || 1969|| Pu production reactor
|-
|-
|Iran|| - || 2011 || Enrichment seems to be the path so far, along with possible future use of the Arak research reactor
| Iran|| - || 2011 || Enrichment seems to be the path so far, along with possible future use of the Arak research reactor
|-
|-
|North Korea || 2006 || - || Pu production reactor
| [[North Korea]] || 2006 || - || Pu production reactor
|-
|-
|Russia||1949||1963|| Pu production reactor
| Pakistan || 1998 || 1971 || Small CANDU may have formed technological basis for Pu production reactors
|-
|-
|UK || 1952 ||1956 || Pu production reactors and uranium enrichment
| [[Russia]] ||1949||1963|| Pu production reactor
|-
|-
|USA||1945||1960|| Pu production reactors and uranium enrichment
| [[United Kingdom|UK]] || 1952 ||1956 || Pu production reactors and uranium enrichment
|-
| [[United States of America|USA]] ||1945||1960|| Pu production reactors and uranium enrichment
|}
|}
<sup>1</sup>Year of first nuclear weapons test.<ref name=b/><br>
<sup>1</sup>Year of first nuclear weapons test.<ref name=b/><br>
<sup>2</sup>Year of first commercial reactor operation.<ref name=a/><ref name=c/><br>
<sup>2</sup>Year of first commercial reactor operation.<ref name=a/><ref name=c/><br>
<onlyinclude>
=Future Threats and Barriers=
</onlyinclude>
{{Image|Proliferation Threats and Barriers IAEA.jpg|right|350px|Table 2. IAEA table of proliferation threats and barriers.<ref name=IAEA/>}}
If nuclear power is to play a major role in decarbonizing our world, there will be thousands of new reactors in many countries, including some that may be tempted to acquire weapons. We must therefore answer some basic questions.
Will deployment of reactors to untrusted countries, or countries that might be taken over by rogue actors, increase the risk of proliferation, either by theft of materials in the reactor, or by modification of the reactor to produce weapons-usable materials? Will fuel processing or other activities connected with nuclear power provide cover for a weapons program or a basis for a quick sprint to bomb making? Will we have adequate safeguards on the production and shipment of vastly increased quantities of fissile material? Will knowledge of the new reactor designs or process technologies lead to easier ways to make bombs?
Answers to these questions are best provided by looking at specific reactor designs. Some designs are more secure than others. See the sections on ''proliferation'' in the articles linked under [[Nuclear_power_reconsidered#New_Reactor_Designs|New_Reactor_Designs]]. We must also look in detail at specific threats and the combination of barriers we are counting on. Threats from a terrorist group trying to hide their activities are very different than from a big country with plenty of resources and a willingness to openly violate any treaties. See Table 2 for a summary from the International Atomic Energy Agency (IAEA).
<onlyinclude>
Minimizing the risk of future proliferation in states that want to buy nuclear reactors or fuel might require one or more barriers:<br>
1) Insisting on full transparency for all nuclear activities in buyer states, including monitoring and inspections by the [[International Atomic Energy Agency]] (IAEA).<br>
2) Limiting fuel processing to just a few supplier states that already have weapons or are approved by the IAEA.<br>
3) Ensuring that fuel at any stage after initial fabrication has an isotopic composition unsuitable for weapons. "Spiking" the initial fuel with non-fissile isotopes, if necessary.<br>
4) Limiting the types of reactors deployed to buyer states. In general, breeders are less secure than burners. Sealed reactor modules are more secure than reactors with on-site fuel processing.<br>
5) Providing incentives and assurances for buyer states to go along with all of the above.<br>
6) Application of diplomatic pressure, sanctions, and other economic measures to non-compliant states.<br>
7) Agreement that any reactor or fuel processing facility declared rogue by the IAEA will be "fair game" for any state feeling threatened.<br>
</onlyinclude>


=Notes and References=
=Notes and References=
<references>
<references>
<ref name=a> https://www.world-nuclear.org/information-library/facts-and-figures/world-nuclear-power-reactors-and-uranium-requireme.aspx
<ref name=a> [https://www.world-nuclear.org/information-library/facts-and-figures/world-nuclear-power-reactors-and-uranium-requireme.aspx World Nuclear Power Reactors & Uranium Requirements] World Nuclear Association Information Library, 2023.
</ref>
</ref>
<ref name=b> Nuclear Ambitions: The Spread of Nuclear Weapons 1989-1990, Leonard S. Spector with Jacqueline R. Smith, Westview Press, 1990; ISBN  0-8133-8075-8.
<ref name=b> ''Nuclear Ambitions: The Spread of Nuclear Weapons 1989-1990'', Leonard S. Spector with Jacqueline R. Smith, Westview Press, 1990; ISBN  0-8133-8075-8.
</ref>
</ref>
<ref name=c> https://pris.iaea.org/pris
<ref name=c> [https://pris.iaea.org/pris IAEA Power Reactor Information System (PRIS)] Comprehensive database on Nuclear Power Reactors in operation, under construction, or being decommissioned.
</ref>
</ref>
<ref name=d> Book
<ref name=IAEA>
''IAEA table of proliferation threats and barriers'', Table 12 in [https://www-pub.iaea.org/mtcd/publications/pdf/te_1450_web.pdf ''IAEA-TECDOC-1450''], 2005.
</ref>
</ref>
</references>
 
</references>[[Category:Suggestion Bot Tag]]

Latest revision as of 12:12, 27 September 2024

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This editable Main Article is under development and subject to a disclaimer.

Nuclear weapons proliferation is one of the four big issues that have held back worldwide deployment of peaceful nuclear power. This article will address the proliferation questions raised in Nuclear power reconsidered.

As of 2022, countries with nuclear weapons have followed one or both of two paths in producing fissile materials for nuclear weapons: enrichment of uranium to very high fractions of U-235, or extraction of fissile plutonium (Pu-239) from irradiated uranium nuclear reactor fuel. The US forged the way on both paths during its World War II Manhattan Project. The fundamental aspects of both paths are well understood, but both are technically challenging. Even relatively poor countries can be successful if they have sufficient motivation, financial investment, and, in some cases, direct or illicit assistance from more technologically advanced countries.

The International Non-proliferation Regime

The International Atomic Energy Agency (IAEA) has a vigorous program to prevent additional countries from acquiring nuclear weapons. The Treaty on the Non-Proliferation of Nuclear Weapons (NPT) is the cornerstone arrangement under which strategic rivals can trust, by independent international verification, that their rivals are not developing a nuclear weapons threat. The large expense of weapons programs makes it very unlikely that a country would start its own nuclear weapons program, if it knows that its rivals are not so engaged. With some notable and worrying exceptions, this program has been largely successful.

Paths to the Bomb

It is frequently claimed that building a civil nuclear power program adds to the weapons proliferation risk. There is an overlap in the two distinct technologies, after all. To build a bomb, one needs Highly Enriched Uranium (HEU) or weapons-grade plutonium (Pu-239). Existing reactors running on Low Enriched Uranium (LEU, under 5% U-235) or advanced reactors running on High Assay LEU (HALEU,up to 20% U-235) use the same technology that can enrich uranium to very high levels, but configured differently. Enrichment levels and centrifuge configurations can be monitored using remote cameras, on-site inspections, and installed instrumentation -- hence the value of international inspections by the IAEA. Using commercial power reactors as a weapons plutonium source is an extremely ineffective, slow, expensive, and easily detectable way to produce Pu. Besides the nuclear physics issues, refueling pressurized water reactors is both time-consuming and obvious to outside observers. That is why the US and other countries developed specialized Pu production reactors and/or uranium enrichment to produce fissile cores for nuclear weapons.

The Historical Record

While nuclear weapons proliferation is a matter of extreme importance, it is not apparent that it is a consequence of a country’s deployment of commercial nuclear reactors. Table 1 lists the countries with both nuclear weapons and operating commercial reactors (as of 2022). There are 33 countries/entities with operating commercial nuclear reactors. Eight, possibly nine, possess nuclear weapons, two of which developed weapons after developing commercial nuclear power. North Korea has nuclear weapons, but no power reactors. Iran is pursuing nuclear weapons, and has power reactors. The Joint Comprehensive Plan of Action (The Iran Nuclear Deal) was based on evidence that Iran’s new Bushehr Russian pressurized water reactors (VVERs) were not part of a weapons program, but that Iran’s uranium enrichment program and its uncompleted research reactor at Arak were.

Table 1. Correlation of commercial nuclear power programs with nuclear weapons programs.
Country  First Weapons1  First Commercial2  Comments 
China 1964 1991 Uranium enrichment
France 1960 1963 UPGG Pu production reactor
India 1974 1969 Pu production reactor
Iran - 2011 Enrichment seems to be the path so far, along with possible future use of the Arak research reactor
North Korea 2006 - Pu production reactor
Pakistan 1998 1971 Small CANDU may have formed technological basis for Pu production reactors
Russia 1949 1963 Pu production reactor
UK 1952 1956 Pu production reactors and uranium enrichment
USA 1945 1960 Pu production reactors and uranium enrichment

1Year of first nuclear weapons test.[1]
2Year of first commercial reactor operation.[2][3]


Future Threats and Barriers

Table 2. IAEA table of proliferation threats and barriers.[4]

If nuclear power is to play a major role in decarbonizing our world, there will be thousands of new reactors in many countries, including some that may be tempted to acquire weapons. We must therefore answer some basic questions. Will deployment of reactors to untrusted countries, or countries that might be taken over by rogue actors, increase the risk of proliferation, either by theft of materials in the reactor, or by modification of the reactor to produce weapons-usable materials? Will fuel processing or other activities connected with nuclear power provide cover for a weapons program or a basis for a quick sprint to bomb making? Will we have adequate safeguards on the production and shipment of vastly increased quantities of fissile material? Will knowledge of the new reactor designs or process technologies lead to easier ways to make bombs?

Answers to these questions are best provided by looking at specific reactor designs. Some designs are more secure than others. See the sections on proliferation in the articles linked under New_Reactor_Designs. We must also look in detail at specific threats and the combination of barriers we are counting on. Threats from a terrorist group trying to hide their activities are very different than from a big country with plenty of resources and a willingness to openly violate any treaties. See Table 2 for a summary from the International Atomic Energy Agency (IAEA).

Minimizing the risk of future proliferation in states that want to buy nuclear reactors or fuel might require one or more barriers:
1) Insisting on full transparency for all nuclear activities in buyer states, including monitoring and inspections by the International Atomic Energy Agency (IAEA).
2) Limiting fuel processing to just a few supplier states that already have weapons or are approved by the IAEA.
3) Ensuring that fuel at any stage after initial fabrication has an isotopic composition unsuitable for weapons. "Spiking" the initial fuel with non-fissile isotopes, if necessary.
4) Limiting the types of reactors deployed to buyer states. In general, breeders are less secure than burners. Sealed reactor modules are more secure than reactors with on-site fuel processing.
5) Providing incentives and assurances for buyer states to go along with all of the above.
6) Application of diplomatic pressure, sanctions, and other economic measures to non-compliant states.
7) Agreement that any reactor or fuel processing facility declared rogue by the IAEA will be "fair game" for any state feeling threatened.


Notes and References

  1. Nuclear Ambitions: The Spread of Nuclear Weapons 1989-1990, Leonard S. Spector with Jacqueline R. Smith, Westview Press, 1990; ISBN 0-8133-8075-8.
  2. World Nuclear Power Reactors & Uranium Requirements World Nuclear Association Information Library, 2023.
  3. IAEA Power Reactor Information System (PRIS) Comprehensive database on Nuclear Power Reactors in operation, under construction, or being decommissioned.
  4. IAEA table of proliferation threats and barriers, Table 12 in IAEA-TECDOC-1450, 2005.