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Technical Steps to Support
Nuclear Arsenal Downsizing
A Report by the APS Panel on Public Affairs
TM
About APS & POPA
The American Physical Society was founded in 1899, with a mission of advancing and diffusing
the knowledge of physics. APS is now the nation’s leading organization of research physicists with
more than 48,000 members in academia, national laboratories, and industry.
This report was overseen by the APS Panel on Public Affairs (POPA).
POPA routinely produces reports on timely topics being debated in government so as to inform
the debate with the perspectives of physicists working in the relevant issue areas. Indeed, APS
has long played an active role in federal government; its members serve in Congress and have
held positions such as Science Advisor to the President of the United States, Director of the CIA,
Director of the National Science Foundation and Secretary of Energy.
Report Committee
Jay Davis, Chair
John Browne
Patricia Lewis
Carolyn Pura
Allen Sessoms
Tom Shea
Francis Slakey
Benn Tannenbaum
Jim Tape
John Taylor
Peter D. Zimmerman
APS Staff
Jodi Lieberman
Jeanette Russo
American Physical Society • 259 14th Street #1050 • Washington DC 20045 • 202-662-8700
Contents
Executive Summary
2
Introduction
3
Verifying Downsizing and Dismantlement
5
Sustaining Capability and Expertise
15
Ensuring Peaceful Uses of Fissile Material
18
Conclusion: Looking to the Future
23
Executive Summary
There is a long history of US Presidents working to reduce the role and the spread of nuclear weap-
ons. Most recently, President Obama voiced America’s commitment “to seek a world without nu-
clear weapons,” while clarifying that “as long as these weapons exist, the United States will maintain
a safe, secure and effective arsenal.”
Science and technology (S&T) will play a critical role in advancing the US plan to balance deter-
rence with downsizing the US nuclear arsenal. In particular, S&T are essential to enable three key
goals associated with this plan:
1) verifying the process of downsizing and dismantling stockpiles;
2) sustaining the capability and expertise to ensure that the remaining arsenal is safe, secure, reliable and
effective for as long as is necessary; and,
3) ensuring the peaceful use of fissile materials.
Consistent with that plan, we recommend the US take the following steps to allow S&T to more
fully sustain and support nuclear arsenal downsizing and nonproliferation:
To support the goal of verifiable downsizing and dismantlement:
•
Declassify the total number of US nuclear weapons - deployed, reserve and retired - and encourage
other nuclear armed countries to do the same.
•
Establish international centers for verification research and validation to serve as test sites for
assessing technologies and methodologies.
•
Support R&D and demonstrations of “nuclear archeology” - a method for examining facilities to
determine past material production - as a step to developing an internationally accepted capability to
validate fissile materials declarations.
To support the goal of sustaining the capability and expertise:
•
Refurbish elements of the US nuclear weapons infrastructure needed to sustain a smaller nuclear
weapons stockpile.
•
NNSA and its laboratories must adapt for the broader nuclear security mission that stockpile
reduction will bring and for the national nuclear security roles that they will play.
To support the goal of ensuring peaceful uses of fissile material:
•
Sustain federal investments in key programs including those to enhance safeguards, detect undeclared
nuclear facilities, and address potential risks associated with global growth of nuclear expertise.
•
Elevate the priority of non-proliferation in the NRC licensing process.
•
Establish a program of information sharing among nuclear-related industries.
Taken together, these steps will provide a strong S&T foundation for nuclear arms reduction pro-
posals and nuclear nonproliferation goals.
Introduction
The current global effort to downsize nuclear arsenals is driven by several
factors: the willingness of the Obama Administration to reengage the arms
control process and to push for lower numbers as the START I Treaty ex-
pires; the anticipated pressures from non-nuclear weapons states before and
during the 2010 Non-Proliferation Treaty (NPT) Review Conference; and
the proposal by Schultz, Perry, Kissinger, and Nunn that setting a goal of
zero nuclear weapons is both timely and credible.1
Nations acquired their nuclear weapons capabilities at great cost to address
their most fundamental security concerns. Before reducing their arsenals
these nuclear-armed nations must be assured that they will continue to be
able to meet those critical security needs.
While individual nuclear-armed nations may undertake unilateral reduc-
tions or even the total elimination of their arsenals, it is more likely to as-
sume reductions will come as a result of negotiated actions undertaken with
some or all remaining nuclear-armed nations. The willingness to pursue and
sustain arsenal reductions will ultimately depend upon how each nation
envisions its ability to balance threats and opportunities against decreased
nuclear capabilities.
Measured steps are essential to progress towards the eventual elimination
of nuclear arsenals. Science and technology (S&T) will play a critical role in
balancing deterrence with nuclear arsenal downsizing and in achieving nu-
clear nonproliferation objectives. In particular, S&T can help manage three
key goals associated with this vision: 1) verifying the process of downsizing
and dismantling of stockpiles, 2) sustaining nuclear weapons capability and
expertise for as long as is necessary, and 3) removing the capabilities for
reversals through various confidence-building measures, in particular by
ensuring the peaceful use of fissile materials.2
These three goals have very particular embedded scientific challenges. For
example, as the numbers of deployed strategic nuclear weapons in the US
and Russian arsenals are reduced to the range of 1,000, agreement between
the United States and the Russian Federation will be required to develop
S&T requirements that include technologies and protocols to increase the
transparency of nuclear weapon and component stockpiles. These include
steps to:
3
•
Establish credible baselines for material and weapons accounting; and,
•
Count warheads on launchers and verify weapons and warheads in storage and
in various stages of dismantlement.
While other nuclear states would not be necessary in discussions at this lev-
el, their involvement would be valuable in follow-on treaties to seek even
further reductions in weapons stockpiles.
At reductions to a level of several hundred, technical requirements will have
to expand to include, for example, technologies and protocols to:
•
Count all deployed and reserve weapons and warheads;
•
Monitor warhead and delivery system production facilities;
•
Track with quantitative measures the movement of weapons and materials,
whether deployed, in dismantlement or in disposal;
•
Assess the production capability of nuclear states; and
•
Increase substantially the security and transparency of the nuclear fuel cycle.
To reach much lower levels (e.g., below 100 per country), there will have to
be an international regime established that eventually includes all nuclear-
armed states and possibly latent nuclear states. The requirements, at a mini-
mum, will include robust and proven technologies and protocols to:
•
Support rigorous multi-national inspection agreements for declared weapons
and facilities;
•
Regulate and monitor the infrastructure necessary to reconstitute a nuclear
force;
•
Conduct comprehensive searches for possible hidden weapons and weapons
programs; and
•
Ensure international transparency in relation to disarmament and control of
all peaceful and non-explosive military uses of fissile material, including all
aspects of the nuclear fuel cycle.
At each stage, methods for building transparency and confidence between
all involved nuclear states are critical. In addition, international agreements
and sanctions must be in place to deal with violator states and rogue actors.
This report identifies several steps that can be taken to advance the S&T
needed to support such nuclear arsenal downsizing. While we believe these
are necessary steps, we recognize they will not be sufficient. Secure down-
sizing of global arsenals will also require diplomatic measures and protocols
that are not the subject of this report. Ultimately, this effort may require a
significant transformation of the international system.
4
Verifying Downsizing
and Dismantlement
Disclosure of Stockpiles
An essential component of robust future nuclear arms reduction agreements
will be the declaration of existing stockpiles of weapons and fissile materials
to establish baseline data against which to measure future reductions. With-
out a declaration that specifies how many and what kind of nuclear materials
are where, it will be difficult - if not impossible - to verify whether a country
is complying with the agreed limitations.
RECOMMENDATION
To establish a meaningful baseline for reductions, this declaration should
include the number of each type of weapon that is deployed, is not deployed
To facilitate international
(whether in an active or inactive reserve), and in the inventory for disman-
monitoring and accounting,
tlement. The accounting should include all weapons, regardless of how they
declassify and make public
are identified (e.g. as strategic or tactical), plus all inventories of fissile ma-
terial. Similar declarations of inventories were an essential initializing step
the total number of US
for the Intermediate-Range Nuclear Forces and the Conventional Forces in
nuclear weapons — active
Europe Treaties.
deployed, active and inactive
reserves, and retired —
This declaration can provide the basis for building the confidence needed
to make sizeable reductions and to analyze and plan the cooperative veri-
together with all inventories
fication policies and technologies required to ensure that each country is
of fissile material committed
abiding by the agreements. The U.S. could take a unilateral step in declas-
to nuclear weapons use,
sifying the number of each type of weapon in its nuclear stockpile while
committed to non-explosive
simultaneously working with Russia to reciprocate as a condition for future
arms reductions. A Russian disclosure, even if made privately to US officials,
military use and to peaceful
would be a major breakthrough in transparency that could catalyze addi-
use, and encourage other
tional global activity on nuclear disarmament. Further public declarations
nuclear-armed states to do
could follow as confidence and transparency increase.
the same — independently
Official disclosure of stockpile numbers by the US and Russia is key to ex-
or as part of future arms
panding agreements from bi-lateral to multi-lateral. Without such a step, it
agreements.
is unlikely that France and China will be willing to engage in arms reduction
agreements. While the UK and France have been open to providing infor-
mation on their deployed stockpiles, other nuclear-armed states have not.
Engaging the nuclear-armed states that are not Parties to the Non-Prolifer-
ation Treaty (NPT) will be more complex and will likely only be achieved
when progress among the P5 (US, UK, France, Russia and China) is tangible,
if then. Information on stockpiles in each nuclear-armed state would allow
each country to evaluate its own requirements for cooperative verification
5
and monitoring as it calculates the impact of nuclear arms reductions on its
national security.
The inventory (amounts, location, and form) of highly-enriched uranium
and plutonium in all nuclear-armed countries should be included as another
confidence-building measure because it provides an indication of a coun-
try’s ability to re-arm in the future.3 This is an important first step in produc-
ing a meaningful fissile material cutoff treaty, which constrains all stocks,
not just newly produced material. As the numbers of weapons are reduced,
similar attention must be paid to monitoring delivery systems, particularly
those with dual capabilities.
Verification Technology
As the numbers of nuclear weapons decrease, any uncertainties in the ar-
senals of other states can become more destabilizing since the number of
weapons needed by them to pose a significant military threat becomes cor-
respondingly smaller. Simply stated, security at 1500 deployed weapons may
be easier to realize than at 25. To accept a commitment to a reduction, each
nuclear-armed state must be confident that its security will not be jeopar-
dized. The verification technology needed to sustain progressive reductions
will provide each state the evidence that all nuclear-armed states are fulfill-
ing their commitments, giving each state added confidence that the threats
of nuclear conflict are diminishing. Each nuclear-armed state must be con-
fident that the verification methods applied within its territory are not used
to acquire any information which is not clearly set forth in verification pro-
tocols, especially not any sensitive information (restricted data) relating to
nuclear weapon design or manufacturing.
The verification challenges are many:
•
First: determine the requirements to verify inventories of special nuclear
material, production capabilities, and numbers of weapons;
•
Second: assess the state of technology necessary to meet those requirements;
•
Third: develop any needed science and technology (S&T);
•
Fourth: determine whether that S&T could reveal information that would
compromise U.S. national security;
•
And fifth: develop methods to protect the security of our assets.
A further challenge is to make certain the verification happens in a man-
ner that does not reveal weapons details to non-nuclear weapon states as
proscribed by Article I of the Nuclear Non-Proliferation Treaty, or classified
information reflecting national security interests and controlled through
relevant U.S. laws and regulations.4
6
Recent monitoring and inspection practices affecting the United States and
Russia focused on verifying the numbers and locations of launchers and de-
livery platforms (and hence deducing the maximum number of warheads
that could be deployed on strategic delivery systems). Modest reductions in
U.S. and Russian stockpile numbers (e.g., 1500) may rely primarily on these
existing practices while more significant reductions in total stockpiles (1000
or fewer) will likely require the use of more intrusive techniques to verify
numbers of warheads. If and when reductions in all nuclear arsenals are
verified by multilateral agreements the techniques employed and the inspec-
tors must guarantee international assurance of compliance.
Each reduction involving nuclear weapons offers possibilities for moni-
toring and verification that can confirm that the states are honoring their
commitments. Verification will likely include two complementary efforts:
confirming declared activities and detecting clandestine materials or opera-
tions. Science and Technology and Research and Development are needed
to enable such steps.
In terms of the diagram below, the verification of declared disposition is
Figure
1
straightforward, paralleling IAEA safeguards on direct-use fissile material in
non-nuclear weapon States. Such verification will require the use of special-
Generic dismantlement
ized methods and managed access.
verification process.
High Explosive Items
Disassembly of
Physics Package
Fissile Material Components
Verify Items
Disposition
Declared to be
Nuclear Weapons
Other Special Materials
Disassembly of other
main components
Non Nuclear Components
A number of storage and dismantlement verification technologies —
focused primarily in the areas of radiation detection, remote monitoring,
and tamper-indicating devices — were developed over the last 15 years to
support a variety of negotiations and exercises. These technologies may be
applicable to support verification throughout the dismantlement process, in-
cluding monitoring and verification of weapons removed from operational
deployment through various storage conditions and disassembly processes
to the end states of disposed uranium and plutonium.
7
High-quality radiation measurements are central to determining that a
weapon or material is - or is not - the item that it is declared to be. Because
of the sensitive information that could be revealed by these measurements,
information protection technologies, or “information barriers”, are available
to permit use of these higher-confidence techniques without divulging sen-
sitive or classified information. The Department of Energy (DOE) and the
Department of Defense (DoD) jointly sponsored a program of development
at the national laboratories during the late 1990s that resulted in information
barrier designs, their incorporation into advanced measurement systems for
potential applications, and the initiation of cooperative development pro-
grams between U.S. and Russian Federation laboratories. Separately, the Tri-
lateral Initiative between the International Atomic Energy Agency (IAEA),
the U.S., and the Russian Federation made substantial progress in develop-
ing information barrier design concepts and a legal framework and deploy-
ment arrangement.
NNSA has continued to support development of second and third genera-
tion versions of these radiation detection and information barrier tech-
niques over the last decade, including limited engagement with scientists
from other countries. Additional development is needed to bring these tech-
nologies to a level of accuracy where they can be confidently deployed in
treaty inspection protocols. In particular, these development efforts would
focus on the required science and engineering for specific applications, au-
thentication processes to ensure the information provided by these systems
can continue to be trusted by all parties, and comprehensive adversarial
analysis, commonly called “red teaming.”
While current information barriers are not perfect, substantial progress has
been made. In the near-term, the negotiation of specific treaties and agree-
ments between the Russian Federation and the United States involving deep
reductions in their stockpiles may require the inclusion of innovative meth-
ods and practices in which US and Russian scientists, security analysts, and
negotiators have greater confidence as a result of this work. Additional work
will be needed before security officials in the U.S. and Russia would grant
approval for the IAEA to carry out any kind of monitoring and before the
IAEA would accept the responsibility for monitoring weapons-related ac-
tivities in the U.S. and Russia. Expanding this type of verification exercise to
other nuclear-armed states would benefit the eventual application of univer-
sal measures.
As these techniques are considered for use in inspection protocols and
transparency measures for warhead verification, dismantlement monitor-
ing, and material storage, they must be critically reviewed by DoD, NNSA,
the Department of State (DoS), the counter-intelligence community, and the
National Security Agency (NSA). Indeed, each nuclear-armed state, as it en-
8
ters into treaties and agreements that would rely on these methods, must de-
termine the acceptability of obligations and verification measures according
to its own national security apparatus. Each state, as well as the IAEA, would
also have to evaluate and select authentication measures to ensure that the
results are meaningful. These reviews will certainly result in design refine-
ments and may reveal the need for new advances in information protection,
radiation measurement techniques, and remote monitoring technologies.
As bilateral US-Russian nuclear stockpile reductions result in arsenals that
no longer dwarf those of other nuclear-armed states, further reductions will
require working with scientists and negotiators from a broader range of
countries. At some point, it may be useful to monitor warhead dismantle-
ment in such a way that the specific model (e.g., W88) can be determined.
Template methods (matching a particular radiation signature) may be use-
ful in addition to attribute measurements (ensuring that certain measured
levels exceed defined limits in order to increase confidence in the contents)
and may prove to be very attractive for some applications. A distinctive tem-
plate would be created for each model and individual samples would then
be compared to the templates on file to confirm (or reject) a declared item.
The templates could include, for example, a combination of passive radia-
tion signatures and/or radiation signatures caused by subjecting an item to
a stream of neutrons and/or gamma rays.
Figure
2
Passive detection techniques are excellent in many situations but they are in-
herently limited by the strength of the signal that reaches the detector from
Depiction of Pulsed
the measured item. For some materials or in cases of inadvertent or inten-
Photonuclear Assessment
tional shielding, active systems may be required.
active measurement
technique.
In active detection systems (Fig. 2), a photon or neutron beam could be
used to stimulate a response from an item that is predictable based on the
(image courtesy Idaho National Laboratory)
Gamma-Neutron Threshold (GNT) Technology
9
radioactive material within the item.5 A transition from passive radiation
measurement techniques to active measurement techniques could provide
higher confidence in weapon and material identification but would require
a challenging confidence building step for implementation. Additional ma-
terials control and accounting methods and remote monitoring techniques
will also emerge as agreements are negotiated with more states and the ex-
pertise and creativity of the international arms control and nonproliferation
technical community are engaged.
The techniques that have received the most attention for the purposes of
warhead or material verification involve passive gamma and neutron mea-
surements. Medium resolution gamma measurements (e.g., by sodium io-
dide (NaI) detectors) could be used to indicate the presence or absence of
plutonium and to match weapon template signatures. High-resolution gam-
ma measurements (e.g., high-purity Germanium detectors) provide, in ad-
dition, the ability to determine isotopic ratios indicative of weapons grade
plutonium and americium content, thus revealing whether the plutonium is
weapons grade, and the time since the last americium separation. In general,
neutron measurement methods ranging from simple neutron counting to
more complex coincidence and multiplicity techniques have been used to
determine plutonium masses.
Measurements of some highly-enriched uranium (HEU) characteristics and
material mass using specially-developed gamma measurement techniques
have been shown to be possible under some carefully-controlled conditions.
It is likely that high confidence measurements of HEU characteristics will
require the use of active interrogation techniques. Experiments and dem-
onstrations using a range of measurement systems - sodium iodide, high-
purity germanium, and helium-3 detectors, as well as neutron multiplicity
counters - have been performed to determine the feasibility and applicabil-
ity of these techniques for potential verification measures.
Authentication of the equipment (ensuring that the measurements taken
and answers given can be trusted when the equipment has been out of the
inspector’s immediate control for extended periods of time) also poses tech-
nical challenges. Research and experimentation have been actively ongo-
ing for a wide variety of applications in this area over the last few decades.
A number of promising methods exist for examining the equipment itself,
the tamper-indicating measures that protect it, the software it employs, and
the data that it provides. A strategy for employing these techniques and a
venue for testing them in a range of scenarios are important next steps in
getting these technologies to the field. Remote monitoring systems - inte-
grating such elements as infrared and video cameras, radiation portal moni-
tors, motion detectors, encrypted RF communications, advanced intrusion
detection, innovative tag and tamper-indicating technologies, and change
10
detection methods - have been developed and implemented to secure a va-
riety of facilities and operations. These systems are key to the secure storage
of sensitive materials and warhead systems of concern in this study.
In addition to these measuring and inventory technologies, the development
of modeling and analytical capabilities to estimate the size of production com-
plexes and assess production rates would be a useful complementary tool.
International Centers for
Verification Research and Validation
Most, if not all, of the technologies described above as candidates for future
arms control verification or confidence-building activities, will require some
form of cooperative development before implementation. Each of these
technologies needs to be tested by multiple parties to ensure robustness and
that all parties are confident in the technology’s operation and function.6
One or more international verification centers would help foster the growth
of a new generation of nonproliferation experts on an international level
and contribute to the maturation process for new technologies to be used in
future arms control activities.
The United States and Russia already have many years of experience in
sharing verification technologies through the Warhead Safety and Security
Exchange (WSSX) program and other initiatives. The establishment of in-
ternational verification centers would allow for additional cooperative veri-
fication and transparency projects between the two countries in an environ-
ment that could stimulate broader multilateral education and involvement.
This, in turn, could motivate the development and implementation of these
systems in support of a wide variety of treaties and agreements.
Further, such verification centers offer the opportunity to develop a truly
international approach to the design, testing, and implementation of these
technologies, provide places to consider and address the varying concerns,
capabilities, and perspectives of non-nuclear weapon states as well as nu-
clear weapon states beyond those actively involved in the past (i.e., Russia,
the U.S., and the UK). Such centers could also provide a useful forum for
interactions with the IAEA so that the considerable experience base devel-
oped by this agency in formulating multilateral technical solutions in the
nuclear safeguards, nuclear security and civilian nuclear power arenas can
be brought to bear around this new set of issues. In addition, these centers
will provide a venue for university experimentation and partnerships so that
key technological advances, innovative academic talent, and critical schol-
arly thinking can be integrated into the technology development process.
11
One technology area that would benefit from the establishment of verifica-
tion centers is that of information barriers. As noted earlier, many of the ba-
sic concepts currently proposed were developed by U.S., Russian and IAEA
teams, with first and second generation systems designed, built, tested, and
evaluated in conceptual and prototype form in the 1990s. A number of U.S.
and Russian laboratories have been involved in proposing and demonstrat-
ing a range of information protection techniques, with limited work cur-
rently ongoing on third generation systems. The designs developed would
greatly benefit from both a reinvigorated review process within each coun-
try’s framework as well as critical review by technologists from a range of
other countries. These design approaches would also benefit from a seri-
ous evaluation of technological advances of the last decade for counterter-
rorism, financial security, and information management applications to see
how they may be integrated with earlier concepts. It should be noted that
application of information barrier principles to active interrogation systems
(including imaging systems) and measurement systems that are not radia-
RECOMMENDATION
tion-detection-based lags behind the development of approaches for passive
Establish international
radiation detection systems.
centers for verification
Significant precedents exist that may serve as models for establishing these
research and validation
centers, including U.S. and Russian Federation transparency projects be-
to serve as test beds
tween design laboratories; Group of Scientific Experts experiments in sup-
for developing and
port of CTBT technology development; IAEA monitoring of civilian nuclear
assessing technologies
operations; the Joint Verification Experiments (JVE) between the US and
USSR for the Threshold Test Ban Treaty, and UK and Norway dismantle-
and methodologies and for
ment transparency exercises.7 The classified nature of the technologies,
building confidence between
measurements, materials, and operations involved will require significant
nuclear armed states.
government oversight. Any centers established will need to balance the attri-
butes of operational realism, classification sensitivities, technical expertise
and required radioactive sources.
There are a number of facilities around the world that may meet the desired
characteristics of such centers and build on the legacy of international co-
operation mentioned above. The UK is working on a “disarmament labora-
tory.” The U.S. has an extensive set of facilities at Kirtland Air Force Base in
Albuquerque, New Mexico, that are specifically designed for arms control
technology development and exercises including the DoD’s Defense Threat
Reduction Agency (DTRA) Technical On-Site Inspection facility (recently
operated under the name Technical Evaluation Assessment Monitor Site),
Sandia’s Cooperative Monitoring Center, and specialized bunkers with fa-
cility-to- facility connections to simulated storage facilities in Russia. The
Nevada Test Site (NTS) has several nuclear facilities, including the Radio-
logical Nuclear Counter-Terrorism Evaluation Complex (RNCTEC) and the
Device Assembly Facility that could be used for simulated exercises and real
dismantlement activities, access to Category I radiation sources for demon-
12
strations and testing, and a range of facilities that can be configured readily
to simulate various portions of the deployment and disassembly cycles. NTS
can also accommodate foreign visitors, as was witnessed by the Joint Verifi-
cation Exercise in 1988. And, it is currently establishing a National Security
Center that would be ideal for testing verification techniques. The Russian
Federation has conducted a number of experiments and demonstrations as
part of cooperative nonproliferation programs with the U.S. at various Ro-
satom and Ministry of Defense facilities. The European Commission Joint
Research Centre at Ispra, Italy, hosted a Trilateral Initiative workshop and
expressed interest in creating an international center for nuclear disarma-
ment research under the auspices of the IAEA.
Such centers should be chosen with specific security missions and corre-
sponding security arrangements in mind. International centers should be
established with consideration of the ability to allow participation of experts
from all nuclear-armed states. The work these centers provide will facilitate
future treaties and agreements.
Nuclear Archeology
As noted above, for sustainable progress to be made towards the goal of ul-
timately eliminating nuclear weapons, nuclear arms treaties will require that
states declare fissile material stockpiles. The accuracy of these declarations
can be confirmed to some degree by examining the records states provide.
When doubts arise as to the accuracy of the records states will apply various
verification methods to test the veracity and to reduce willful cheating. One
technique called “nuclear archeology” may offer new and promising tools to
certifying completeness and accuracy.
In general, nuclear archeology is the study of nuclear facilities or fissile ma-
terials to determine historical information, to identify the source or mor-
phology of specific material samples. Nuclear archeology employs a set
of methods and tools that can be used to characterize past fissile material
production activities. It does this by using measurements and samples at
production and storage sites and direct measurements of samples of fissile
materials or related feed and waste materials. While the technique cannot
remove all uncertainty in a declaration, it can provide additional evidence
of the overall operation of nuclear facilities and therefore identify amounts
of plutonium and uranium production.
In one application, the isotopic composition of a reactor core and other com-
ponents are measured with the goal of determining the reactor’s operating
history. Long-lived radionuclides produced by neutron absorption in natu-
rally occurring nuclei will reside in the permanent components of a reactor
13
core. By analyzing several samples of concentrations of the radionuclides in
the reactor core and combining that with assumptions about the design and
operation of the reactor, accurate upper limits can be determined of how
much plutonium could have been produced by that reactor. That estimate
can then be compared to the state’s materials declaration and the operat-
ing records provided. While the technique cannot remove all uncertainty, it
can provide additional evidence of how nuclear facilities have operated and
therefore identify amounts of plutonium and uranium production.
U.S. experience shows that, even with full access and disclosure, it is often
difficult to accurately account for all materials produced. This fact will need
to be taken into account to ensure that a procedure designed to increase
confidence does not inadvertently reduce it. One goal might be to have vari-
ous states provide national data in order to establish an acceptable interna-
tional range for “Material Unaccounted For.”
RECOMMENDATION
Analyzing specific samples of fissile material may allow for the determina-
Support nuclear
tion of the date and site of production and the facility-specific process char-
archeology R&D and
acteristics to be identified. Verifying plutonium declarations is easier than
verifying uranium declarations. Uranium characteristics can be determined
demonstrations as a
through the measurement of the minor isotopes (esp. 232U and 234U, 236U after
step to developing
irradiation) and protactinium in-growth, thus providing additional data to
an internationally
verify the accuracy of the uranium enrichment records.
accepted capability to
The fundamental techniques of nuclear archeology, while well established,8
validate fissile materials
have not, to date, been applied rigorously to the validation of materials dec-
declarations.
larations. It is our opinion that an R&D effort connected to demonstration
projects with U.S. and Russian reactors and enrichment facilities can pro-
vide the necessary foundation for incorporating this technique into future
reduction initiatives.
14
Sustaining Capability
and Expertise
The Nuclear Weapons Infrastructure
Each nuclear-armed state will require that its national security not be under-
mined as progress is made towards downsizing nuclear arsenals. Obviously,
the threats posed and the functional capabilities of a state will change over
time, with or without arsenal reductions. Each state is more likely to accept
new commitments to increasing reductions if it is proceeding from a posi-
tion of strength, confident in its capabilities. Nuclear disarmament is likely
to require a number of incremental reductions over time to carry out the
associated changes and to adjust to the new realities.
At every point in this process, regardless of the size of the U.S. stockpile,
it will be necessary to maintain the technical skills and special facilities to
guarantee that remaining weapons will function if they are ever required to
do so, and to verify they will remain safe against accidents and secure against
unintended use. This can only be accomplished if steps are taken to maintain
the nuclear design, engineering and manufacturing expertise to certify the
safety, security, reliability, and effectiveness of all remaining weapons, and to
maintain the capability to re-arm if other nuclear-armed states threaten U.S.
national security. The Stockpile Stewardship Program has been remarkably
successful in accomplishing this mission without nuclear testing for the past
15 years, but its continued success requires the support of the expertise and
capabilities of the weapons labs, the Nevada Test Site, and U.S. production
plants. Many of these skills and facilities cannot be found in universities,
other government laboratories, or in U.S. industry today.
This nuclear weapons infrastructure is no longer directly proportional to
the size of the stockpile because the number of skilled workers and facili-
ties does not scale with the number of weapons. While such proportionality
existed when the U.S. was designing, testing, and building a large number
of weapons and types, today there exists a floor below which the size of the
complex cannot go if it is to maintain any competence in nuclear weapons-
related activities. Both the Obama Administration and Congress will need
to recognize this fact, size the complex accordingly, and provide the funding
to sustain it. As an example, reducing the number of weapons by 50 percent
does not mean the number of plutonium experts can be similarly reduced
since plutonium expertise is required to maintain all nuclear weapons and
not just a particular system. In a similar argument, if the weapons program
15
requires a nuclear facility to build or to examine plutonium pits, the equip-
ment in the facility to handle 10 plutonium pits/year might be the same as
handling 50/year or more.
Many recent high-level reviews of the current state of the U.S. nuclear weap-
ons infrastructure have concluded that the U.S. must address the decaying
infrastructure and the aging expertise to competently continue the mission
of managing the stockpile through certifiable changes in the enterprise.
A group within the NNSA complex is studying and implementing ways to
integrate the various capabilities across nuclear sites to reduce and remove
redundancies. This group, the National Security Enterprise Integration
Committee, includes senior representatives from the laboratories, the Ne-
vada Test Site, and production facilities. It will be necessary to continually
review downsizing and consolidation efforts to ensure the remaining skills
RECOMMENDATION
and facilities are adequate to carry out the mission. However, the nuclear in-
frastructure requires a level of recapitalization that must be consistent with
Refurbish elements of
the projected needs of the stockpile for the next 20-30 years. This is estimat-
the US nuclear weapons
ed to be an expensive undertaking, but the alternative of operating outdated
facilities could be more expensive, due to an inability to maintain the stock-
infrastructure needed to
pile in these facilities (at any size) in a cost-effective and secure manner.
sustain a safe, secure and
smaller stockpile for as
For the stockpile stewardship program, the expertise must cover the theo-
long as is needed.
retical and experimental base of the nuclear designs in our stockpile. This
expertise covers a broad set of technical fields including nuclear physics and
systems engineering, materials science, chemistry, computer science, and
conventional high explosives. Some of these fields, e.g. actinide chemistry,
have not been in great demand outside the nuclear weapons program and
therefore it may be necessary, in certain disciplines, to subsidize university
research and Ph.D. programs to provide the expertise needed to maintain
the stockpile.
The expertise needed in the production complex to manufacture necessary
replacement parts will also require attention because of significant retire-
ments over the last decade. This challenge parallels the problems at the labs
since production expertise results partially from the hands-on experience
that is acquired by building or modifying actual weapons. A close collabo-
ration between labs responsible for certification and plants responsible for
production has always been important. As the weapons age, and materials or
replacement parts are required, this collaboration will be critical to ensure
the proper skills, tools, and processes are available to certify the weapons
after production and prior to re-entering the stockpile.
16
SUSTAINING CAPABILITIES AT THE
NUCLEAR WEAPONS LABORATORIES
As mentioned in the previous section, the human resources and expertise
and the technical capabilities needed to maintain the nuclear weapons, non-
proliferation, nuclear counter-terrorism and treaty verification programs of
the United States do not scale in any simple way with the number of weap-
ons in the stockpile. Both the National Nuclear Security Administration
and the nuclear weapons laboratories must embrace the larger role of the
nuclear security mission as the resources devoted to the stockpile mission
itself are reduced over the long term. Within their nuclear security mission,
the tools of the traditional nuclear weapons program are required to solve
issues such as nuclear weapons control, inventory and dismantlement under
treaty regimes, nuclear forensics and nuclear archaeology, identification and
defeat of improvised nuclear devices, and intelligence studies. Additionally,
the DOE/NNSA laboratories have contributed significantly to non-nuclear
RECOMMENDATION
weapons programs and security programs outside the DOE, most notably to
those of the DoD, the intelligence and law enforcement communities, and
NNSA and its laboratories
the Department of Homeland Security.
must adapt for the broader
nuclear security mission
To sustain their capabilities over the long term, the nuclear weapons labora-
that stockpile reduction will
tories and NNSA must thoughtfully recast themselves for the larger national
nuclear security mission, understanding that within their specific nuclear
bring and for the national
mission they must think as multi-program laboratories, not just as weapons
nuclear security roles that
design laboratories. Each of the nuclear weapons laboratories has specific
they will play.
successes of such behavior in individual isolated technical or disciplinary
areas. There is opportunity for entrepreneurial behavior to become more
generalized and thus enable attracting personnel and investment that will
further the state-of-the-art intellectual and infrastructure capital capabilities
needed to maintain the nuclear weapons, non-proliferation, nuclear coun-
ter-terrorism and treaty verification programs of the United States. The chal-
lenge to NNSA and its laboratories is one of both attitudes and practices.
17
Ensuring Peaceful Uses of
Fissile Material
As nuclear arsenals are substantially reduced, there will be an even greater
need to manage fissile material and the growth of nuclear expertise. High
confidence in the security mechanism to prevent nuclear terrorism and to
insure the peaceful uses of fissile materials will be essential to significant
downsizing. A strong nonproliferation regime and robust security at nuclear
facilities that addresses the challenges of rogue states and terrorists, and lim-
its the spread of sensitive nuclear technologies are central components for
a world with fewer nuclear weapons. The resurgence in interest in nuclear
power only increases the urgency and importance of taking steps now.
The U.S. has created important partnerships, such as the Cooperative Threat
Reduction program, the Global Initiative to Combat Nuclear Terrorism,
and the Proliferation Security Initiative to address many concerns associ-
ated with nuclear terrorism. While R&D is important to their success, these
efforts generally do not support new R&D efforts to improve capability and
are not relevant to this discussion.
Federal Programs
There are numerous, well-established activities and programs set up to man-
age the security and peaceful uses of fissile material. This section identifies a
few of these critical S&T-based federal programs. It is intended to illustrate
the key role that S&T plays in achieving stable reductions.
Safeguards are essential to providing confidence in the peaceful uses of
nuclear energy, and are implemented in various ways. The IAEA provides
international safeguards; Euratom and the Argentine-Brazilian Agency for
Accounting and Control of Fissile Materials provide regional safeguards;
and various nuclear supply agreements provide bilateral safeguards.
Effective and efficient safeguards depend on technology and technical ex-
pertise. These technologies include methods to detect and measure quanti-
ties of fissile materials, information management and environmental sample
collection and analysis systems, overhead imagery acquisition and analysis,
and unattended and remote monitoring systems. Safeguards expertise re-
quires an understanding of the complete nuclear fuel cycle, nuclear weapons
proliferation pathways, the capabilities and limitations of safeguards tech-
nologies, and safeguards concepts and approaches.
18
Safeguards technology and expertise are also critical to monitoring the
downsizing of nuclear arsenals, including a fissile material cutoff treaty, fis-
sile materials disposition, and some aspects of overall weapons dismantle-
ment. In addition, this technological expertise is used for nuclear security
in a variety of ways to protect against terrorist threats to fissile materials and
facilities.
In late 2008, NNSA began the Next Generation Safeguards Initiative (NGSI)
in part to reverse a steady decline in safeguards R&D and technical exper-
tise.10 The NGSI focuses on five main areas: safeguards policy and outreach,
safeguards concepts, technology, human resources, and infrastructure devel-
opment. Strong fiscal support for NGSI is critical to ensure its appropriate
integration with related programs within DOE/NNSA and other agencies. It
is particularly important to further develop and improve methods to detect
undeclared fissile materials and activities, and human resource development.
RECOMMENDATION
For the past several years, the U.S. Department of State (DOS) has run a
successful program to improve bioethics and biosafety among life scientists
Sustain federal investments
in Southeast Asia. In late 2008, DOS created the Nuclear Security Assistance
in key supporting activities
Program (NSAP) program to work with nuclear scientists. Currently active
including the Next
in Morocco and Algeria, this program is expected to expand to eight more
Generation Safeguards
countries in the Middle East/North Africa region by 2011. This program
focuses on smaller, fledgling nuclear programs in countries that do not yet
Initiative, R&D on
have substantial existing facilities.
technologies to detect
undeclared fissile materials
At present, the program addresses technical issues relating to civilian nu-
facilities, and the Nuclear
clear power and other topics requiring civilian nuclear expertise. Program
activities include:
Security Assistance Program
to address potential risks
•
Providing training and community building to develop effective, low-
associated with global
cost educational opportunities for scientists and engineers to lead to the
growth of nuclear experts.
development and implementation of best practices in nuclear security and
safety; and
•
Funding design and construction of regional nuclear medicine facilities.
One indication of program success for DOS would be the willingness of in-
ternational partners and/or host states to bear a greater proportion of long-
term costs and responsibility for the instigation of and sustainability of these
training programs.
DOS initiated the program in the Middle East/North Africa region—where
several countries expressed interest in nuclear power— due to existing area
DOE programs. DOS plans to expand this program to other countries, but
will require additional funding and resources. While working with Libya,
19
Syria, Pakistan, North Korea and Iran would likely be productive, legal and
political challenges remain. A small program to create a regional nuclear
medicine center based in Libya was stalled in early 2008. DOS requires White
House guidance for working with Syria; under the last Administration the
DOS was not authorized to work with Syria. The current political climate
makes it nearly impossible for DOS to engage with both DPRK and Iran.
Experts from non-governmental organizations, such as the World Institute
for Nuclear Security, are working with DOS to identify in-country person-
nel needed for partnerships as well as how to assist in training. This program
could be expanded to include other non-government organizations to help
run training programs or regional workshops.
Licensing
Nuclear arsenal downsizing is most likely to occur if the U.S. and others
RECOMMENDATION
believe the problem of proliferation is addressed through all practicable
means. The role of the licensing and regulatory communities in nonprolif-
NRC should adequately
eration is often overlooked. To ensure appropriate regulatory and licensing
address the non-
framework, and, in particular, to ensure there is appropriate development
proliferation threats of
and understanding of S&T within the regulatory and licensing cultures,
new technologies in their
nonproliferation considerations must be an integral part of the calculus in
licensing process.
decision-making.
Over the next several years, the Nuclear Regulatory Commission will be
reviewing license applications for new technologies that could carry sub-
stantial proliferation risks. As arsenals are downsized, high confidence must
be maintained in the peaceful uses of fissile material and NRC assessments
will thereby take on even greater significance.
The NRC’s 2004-2009 strategic plan (NUREG-1614) details how the NRC
will prevent any “instances where [NRC] licensed radioactive materials are
used domestically in a manner hostile to the security of the United States.”11
The strategic plan also notes that the NRC will:
… coordinate with Federal and international counterparts to provide
appropriate security and control to prevent the proliferation of special
fissile materials and nuclear technology and to reduce the potential for
harmful use of high-risk radioactive material.12
The NRC has three nonproliferation-related roles and has responsibility to:13
•
Enforce US treaty and agreement obligations at domestic nuclear facilities;
•
Enforce physical security and all other safeguards at domestic nuclear facilities;
and
•
To enforce export-import licensing regulations for specific lists of nuclear-
related items.
20
In addition, the NRC provides considerable consultation and training
support for a wide variety of domestic and international nonprolifera-
tion activities.
Each of these requirements must be addressed during the licensing process.
Prospective licensees must include specific details about how they intend to
comply with physical protection and material accounting standards man-
dated by agreements such as the US-IAEA Safeguards Agreement and the
Additional Protocol to that agreement. The NRC also issues import licenses
for certain imported nuclear-related items.
While the NRC has laid out a compelling strategic plan that appears to in-
clude nonproliferation at the proper level of importance, it is critical that the
NRC make nonproliferation a priority, in fact and in practice. At this time,
based on publicly available NRC documents, nonproliferation is not an ob-
vious part of the license evaluation.14 The U.S. Congress should consider
RECOMMENDATION
appropriate legislation to ensure adequate attention to nonproliferation over
the long term.
Establish a program
of information sharing
among relevant nuclear-
Industry Role
related industries.
Broadening industry involvement in nonproliferation could provide sig-
nificant new capabilities to prevent the spread or diversion of nuclear, ra-
diological, or dual-use material or technology. As a complement to existing
government efforts industry can also be an important first line of defense in
detecting and thwarting proliferation, such as illicit trade networks or insid-
er theft. While the Nuclear Suppliers group is a valuable non-proliferation
mechanism, the current level of information-sharing should be strength-
ened.15 Such sharing will only be successful if it is sensitive to issues of pro-
prietary information and marketplace competitiveness.
Independent analysis of this problem has considered how establishing ef-
fective information sharing can be a good business decision in addition to
being a good national security decision.16 The authors of this independent
analysis surveyed dozens of companies to determine responsible and practi-
cal first steps and concluded:
“Because industry is closest to users of the goods and technology
that could be illicitly diverted throughout the supply chain, industry
information can potentially be more timely and accurate than other
sources of information. Industry is in an ideal position to help ensure
that such illicit activities are detected. This role could be performed
more effectively if companies worked together within a particular
industry to promote nonproliferation by implementing an industry-
wide governance/self-regulation program.”
21
Performance measures would be used to ensure that materials and technolo-
gies are secure throughout supply chains and that customers are legitimately
using and maintaining oversight of these items. This approach is broader
than internal compliance programs (ICPs) implemented by individual com-
panies. While an ICP focuses narrowly on a system a particular company
has developed to ensure and promote compliance with existing regulations,
broader industry self-governance is required to contribute to global nonpro-
liferation.
The PNNL report determined that several companies are already engaging
in information sharing and self-regulation. While their recommendation for
more extensive voluntary information-sharing requires further assessment
by policy makers, the need for action is well documented.
22
Conclusion:
Looking to the Future
This report identifies near-term technical steps to support the goal of sub-
stantial reduction in the global numbers of nuclear weapons.
The standard military assessment of a problem is that the solution lies in
the trade space between technology, doctrine and operations. We find that
although technology is a common thread through all our recommendations
these recommendations must be supported by these other two other com-
ponents for a solution. As physicists, these other components lie outside the
scope of our report, as do the political and diplomatic aspects of the issues.
Three critical science and technology challenges must be addressed;
1) verifying and monitoring arms control treaties, including dismantlement
efforts;
2) sustaining nuclear weapons expertise as long as it is necessary, not just to
support the deployed stockpile, but also to support nuclear counter terrorism,
nuclear forensics and archeology, and materials control and monitoring
programs as required;
3) insuring that the nuclear power enterprise is appropriately monitored and
regulated to ensure peaceful use of fissile materials.
Even as the number of nuclear weapons decreases there remains a significant
challenge to monitoring and assuring mutual security. The near-term steps
we identify may be funded and staffed as an extrapolation of past expen-
ditures. However, longer term steps will require new partners and broader
engagement in the development, assessment and use of monitoring tools.
The costs and staffing associated with these longer term steps may rival the
investments currently needed to keep the deployed stockpile credible, safe
and secure.
We are confident that the development of the technology needed for a safe
and secure downsizing program for global nuclear arsenals is within our
reach if it is adequately supported. The associated operational and doctrinal
measures will require major investments as well. The technology steps are
clear; the structure of the overall program requires careful assessment and
ongoing support.
23
Endnotes
1
George P. Shultz, William J. Perry, Henry A. Kissinger, and Sam Nunn, A World Free of Nuclear
Weapons, The Wall Street Journal, January 4, 2007. Since then, similarly distinguished individu-
als in, for example, the UK, Germany, France, Italy, Norway and Australia have joined in calling
for global nuclear disarmament.
2
“Fissile material” as used in this report includes radionuclides that are or could be used in nucle-
ar weapons without further isotopic enhancement. Fissile material includes plutonium contain-
ing appreciable percentages of 239Pu, 241Pu; uranium containing in excess of 20% 235U, 12% 233U,
and neptunium or americium.
3
This may also require the declaration of the historical data relative to stockpile sizes and compo-
sitions by weapon types.
4
5
It is important to note that such systems can be designed to different levels of certainty, bearing
in mind that increasing the dimensions of a template to include geometric factors, for example,
raises the requirements on security approvals for its use. Such methods can only be expected to
be adopted if they are developed by and demonstrated to all parties involved.
6
These tests must be carried out without revealing classified information to inspectors or to third
parties.
7
8
Nuclear Archaeology: Verifying Declarations of Fissile-Material Production, Steve Fetter, Science
and Global Security, 1993, Volume 3, Issue 3, page 237-259.
9
These issues were dealt with in America’s Strategic Posture: The Final Report of the Congressional
Commission on the Strategic Posture of the United States, Chapter 6 and in The Henry L. Stimson
Center, Leveraging Science for Security: A Strategy for the Nuclear Weapons Laboratories in the
21st Century, March 2009.
10
Nuclear Power and Proliferation Resistance: Securing Benefits, Limiting Risk, Nuclear Energy
resistance/upload/proliferation.pdf
11
glance.pdf
12
Ibid.
13
Ibid.
14
15
G. Hund, A. Seward, Broadening Industry Governance to Include Nonproliferation, PNWCGS
Publication, PNNL-17521.
16
Ibid.
24
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