GAO-10-883T, Combating Nuclear Smuggling: DHS Has Made Some Progress but Not Yet Completed a Strategic Plan for Its Global Nuclear Detection Efforts or Closed Identified Gaps


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Testimony: 

Before the Committee on Homeland Security and Governmental Affairs, 
U.S. Senate: 

United States Government Accountability Office: 
GAO: 

For Release on Delivery: 
Expected at 10:00 a.m. EDT: 
Wednesday, June 30, 2010: 

Combating Nuclear Smuggling: 

DHS Has Made Some Progress but Not Yet Completed a Strategic Plan for 
Its Global Nuclear Detection Efforts or Closed Identified Gaps: 

Statement of Gene Aloise, Director,
Natural Resources and Environment: 

GAO-10-883T: 

GAO Highlights: 

Highlights of GAO-GAO-10-883T, a testimony before the Committee on 
Homeland Security and Governmental Affairs, U.S. Senate. 

Why GAO Did This Study: 

In April 2005, a Presidential Directive established the Domestic 
Nuclear Detection Office (DNDO) within the Department of Homeland 
Security (DHS) to enhance and coordinate federal, state, and local 
efforts to combat nuclear smuggling abroad and domestically. DNDO was 
directed to develop, in coordination with the departments of Defense, 
Energy, and State, an enhanced global nuclear detection system of 
radiation detection equipment and interdiction activities. (DNDO 
refers to this system as an architecture.) DNDO is to implement the 
domestic portion of the architecture. Federal efforts to combat 
nuclear smuggling have largely focused on established ports of entry, 
such as seaports and land border crossings, and DNDO has also been 
examining nuclear detection strategies along other pathways. 

Over the past 7 years, GAO has issued numerous recommendations on 
nuclear or radiological detection to the Secretary of Homeland 
Security, most recently in January 2009. This testimony discusses the 
status of DHS efforts to (1) complete the deployment of radiation 
detection equipment to scan all cargo and conveyances entering the 
United States at ports of entry, (2) prevent smuggling of nuclear or 
radiological materials via the critical gaps DNDO identified, and (3) 
develop a strategic plan for the global nuclear detection 
architecture. GAO’s testimony is based on prior work that was updated 
by obtaining DHS documents and interviewing DHS officials. 

What GAO Found: 

DHS has made significant progress in both deploying radiation 
detection equipment and developing procedures to scan cargo and 
conveyances entering the United States through fixed land and sea 
ports of entry for nuclear and radiological materials since GAO’s 2006 
report. While DHS reports it scans nearly 100 percent of the cargo and 
conveyances entering the United States through land borders and major 
seaports, it has made less progress scanning for radiation (1) in 
railcars entering the United States from Canada and Mexico; (2) in 
international air cargo; and (3) for international commercial aviation 
aircraft, passengers, or baggage. 

DHS efforts to prevent the smuggling of nuclear and radiological 
materials into the United States through gaps DNDO identified in 
developing the nuclear detection architecture remain largely 
developmental since GAO’s 2009 report. The gaps DHS identified include 
land border areas between ports of entry into the United States, 
international general aviation, and small maritime craft such as 
recreational boats and commercial fishing vessels. These gaps are 
important because of their size, volume of traffic, and the difficulty 
of deploying available radiological and nuclear detection 
technologies. DHS’s actions to address these gaps consist primarily of 
efforts to develop, test, and deploy radiation detection equipment; 
conduct studies or analyses to identify and address particular threats 
or gaps; develop new procedures to guide scanning for radiation; and 
develop and learn from pilot programs. 

DHS does not yet have a strategic plan for the global nuclear 
detection architecture, but DHS officials said they began working on a 
plan earlier this year and expect to complete it by fall 2010––2 years 
after GAO last recommended this to DNDO—and more than 7 years after we 
first identified the need for a comprehensive plan in October 2002. 
The lack of a strategic plan has limited DHS’s efforts to complete 
such an architecture, because although each agency with a role in 
combating nuclear smuggling has its own planning documents, without an 
overarching strategic plan, it is difficult to address the gaps and 
move to a more comprehensive global nuclear detection strategy. DNDO’s 
4-year effort to develop an advanced radiation detection monitor is an 
example of the consequences of not having a strategic plan and not 
reaching consensus on such a plan with other federal agencies. In GAO’
s view, the proposed deployment of this monitor distracted DNDO from 
its mission to fully deploy the architecture and close the gaps it 
identified. Also, in 2006 GAO recommended that the decision to deploy 
this monitor be based on an analysis of both benefits and costs—which 
GAO later estimated at over $2 billion—and a determination of whether 
any additional detection capability provided by the monitor was worth 
its additional cost. DNDO proceeded with ASP testing without fully 
completing such an analysis. Further, DNDO focused this monitor 
deployment effort on replacing components of the architecture where a 
radiation detection system was already in place––at established ports 
of entry––and shifting its focus away from closing the gaps it 
identified in the architecture. 

View [hyperlink, http://www.gao.gov/products/GAO-10-883T] or key 
components. For more information, contact Gene Aloise at 202-512-3841 
or aloisee@gao.gov. 

[End of section] 

Mr. Chairman and Members of the Committee: 

I am pleased to be here today to discuss the Domestic Nuclear 
Detection Office's (DNDO) efforts to develop a global nuclear 
detection architecture--an integrated system of radiation detection 
equipment and interdiction activities to combat nuclear smuggling in 
foreign countries, at the U.S. border, and inside the United States--
and to provide an update on the deployment of radiation detection 
equipment at U.S. borders. Preventing terrorists from using 
radiological or nuclear material to carry out an attack in the United 
States is a top national priority. DNDO, within the Department of 
Homeland Security (DHS), is charged with enhancing and coordinating 
federal, state, and local efforts to prevent radiological and nuclear 
attacks.[Footnote 1] Among other things, DNDO is required to 
coordinate with other federal agencies to develop an enhanced global 
nuclear detection architecture. It is also responsible for developing, 
acquiring, and deploying radiation detection equipment to support the 
efforts of DHS and other federal agencies. While federal efforts to 
combat nuclear smuggling have largely focused on established ports of 
entry, such as seaports and land border crossings, DNDO has also been 
examining nuclear detection strategies along other potential pathways 
and has identified several gaps in the architecture, including (1) 
land border areas between ports of entry into the United States; (2) 
international general aviation; and (3) small maritime craft, such as 
recreational boats and commercial fishing vessels. 

Even before DNDO's inception in 2005, we were highlighting the need 
for a more comprehensive strategy for nuclear detection. In 2002, we 
reported on the need for a comprehensive plan for installing radiation 
detection equipment, such as radiation portal monitors, at all U.S. 
border crossings and ports of entry that (1) addresses vulnerabilities 
and risks; (2) identifies the complement of radiation detection 
equipment that should be used at each type of border entry point--air, 
rail, land, and sea--and whether equipment could be immediately 
deployed; (3) identifies longer-term radiation detection needs; and 
(4) develops measures to ensure that the equipment is adequately 
maintained.[Footnote 2] More recently, in July 2008, we testified that 
DNDO had still not developed an overarching strategic plan,[Footnote 
3] and recommended that DHS coordinate with the Departments of 
Defense, Energy, and State to develop one. In January 2009, we 
recommended that the Secretary of Homeland Security develop a 
strategic plan for the domestic part of the global nuclear detection 
strategy to help ensure the success of initiatives aimed at closing 
gaps and vulnerabilities.[Footnote 4] We stated that this plan should 
focus on, among other things, establishing time frames and costs for 
the three gaps DNDO had identified--land border areas between ports of 
entry, aviation, and small maritime vessels. DHS agreed with the 
recommendation that we made in our 2008 testimony on the need for an 
overarching strategic plan to guide future efforts to combat nuclear 
smuggling and move toward a more comprehensive global nuclear 
detection strategy. 

In addition, since 2006, we have been reporting on longstanding 
problems with DNDO's efforts to deploy advanced spectroscopic portal 
(ASP) radiation detection monitors, a more advanced and significantly 
more expensive type of radiation portal monitor to replace the 
polyvinyl toluene (PVT) portal monitors in many locations that the 
Customs and Border Protection (CBP), an agency within DHS, currently 
uses to screen cargo at ports of entry.[Footnote 5] We have issued 
seven reports and testified before Congress five times identifying 
problems with the cost and performance of the ASPs and the lack of 
rigor in testing this equipment. For example, we found that tests DNDO 
conducted in early 2007 used biased test methods that enhanced the 
apparent performance of ASPs and did not use critical CBP operating 
procedures that are fundamental to the performance of current 
radiation detectors.[Footnote 6] In addition, in 2008 we estimated the 
lifecycle cost of each standard cargo version of the ASP (including 
deployment costs) to be about $822,000, compared with about $308,000 
for the PVT standard cargo portal monitor, and the total program cost 
for DNDO's latest plan for deploying radiation portal monitors to be 
about $2 billion. Based in part on our work, DHS informed this 
committee in February 2010, after spending over $224 million, that the 
department had scaled back its plans for development and use of ASP 
technology. However, this $224 million figure does not include the 
considerable cost of physical testing of ASPs at national labs, the 
Nevada Test Site, and field validation at working ports of entry at 
land borders and seaports. We have asked DNDO for this information, 
and DNDO officials are in the process of providing it to us. 

As I will discuss today, while some progress has been made, DHS and 
other federal agencies have yet to fully address critical gaps in the 
global nuclear detection architecture. Specifically, my testimony 
discusses the status of DHS efforts to (1) complete the deployment of 
radiation detection equipment to scan all cargo and conveyances 
entering the United States at ports of entry, (2) prevent smuggling of 
nuclear or radiological materials via the critical gaps DNDO 
identified, and (3) develop a strategic plan for the global nuclear 
detection architecture. 

My testimony is based on our prior work on U.S. government efforts to 
detect and prevent the smuggling of nuclear and radiological materials 
from October 2002 through January 2009,[Footnote 7] and details on the 
scope and methodology for those reviews are available in our published 
reports. With information from DHS officials, we updated our prior 
work on (1) DHS's deployment of radiation detection equipment since we 
last reported on this topic in 2006 and (2) DHS efforts to develop a 
strategic plan since we last reported on this topic in 2009. We 
conducted the work for this performance audit in accordance with 
generally accepted government auditing standards. Those standards 
require that we plan and perform the audit to obtain sufficient, 
appropriate evidence to provide a reasonable basis for our findings 
and conclusions based on our audit objectives. We believe that the 
evidence obtained provides a reasonable basis for our findings and 
conclusions based on our audit objectives. 

DHS Scans Almost All Cargo and Conveyances Entering the United States 
through Land Borders and Major Seaports but Is Still Developing 
Options to More Systematically Scan Rail, Air Cargo, and Commercial 
Aviation: 

DHS has made significant progress in deploying both radiation 
detection equipment and developing procedures to scan cargo and 
conveyances entering the United States through fixed land and sea 
ports of entry for nuclear and radiological materials. Specifically, 
DHS has deployed nearly two-thirds of the more than 2,100 radiation 
portal monitors identified in its deployment plan--over 1,400--but 
needs to deploy more than 700 more to complete the plan. According to 
DHS officials, the department scans nearly 100 percent of the cargo 
and conveyances entering the United States through land borders and 
major seaports. However, DHS has made less progress scanning for 
radiation (1) in railcars entering the United States from Canada and 
Mexico; (2) in international air cargo; and (3) for international 
commercial aviation aircraft, passengers, or baggage. 

Land Ports of Entry: 

According to DHS officials, since November 2009 almost all non-rail 
land ports of entry have been equipped with one or more PVTs. Of the 
over 1,400 radiation portal monitors deployed, 885 PVTs have been 
deployed along the northern and southern borders of the lower 48 
states to all but a few non-rail ports of entry. At present, 100 
percent of all cargo, conveyances, drivers, and passengers driving 
into the United States through commercial lanes at land borders are 
scanned for radiation, as are more than 99 percent of all personally 
operated vehicles (non-commercial passenger cars and light trucks), 
drivers, and passengers. 

Seaports: 

According to DHS officials, the department now scans nearly all 
containerized cargo entering the U.S. seaports for nuclear and 
radiological materials. Specifically, in addition to the PVTs deployed 
for land ports of entry, DHS has deployed 444 PVTs to major American 
seaports--including the largest seaports accounting for the majority 
of cargo. However, some smaller seaports that receive cargo may not be 
equipped with PVTs. DHS officials stated that current deployment plans 
have been in place to address all the remaining gaps in the deployment 
of PVTs to seaports but that current and future budget realities 
require a complete re-planning of the deployment schedule. 

International Rail: 

At present there is limited systematic radiation scanning of the 
roughly 4,800 loaded railcars in approximately 120 trains entering the 
United States each day from Canada and Mexico through 31 rail ports of 
entry. Much of what scanning for radioactive materials takes place at 
these ports of entry is conducted with portable, hand-held radioactive 
isotope identification devices (RIID). Such scans are triggered when, 
for example, anomalous readings are detected from imaging scans of 
rail car contents. According to DHS officials, international rail 
traffic represents one of the most difficult challenges for radiation 
detection systems due to the nature of trains and the need to develop 
close cooperation with officials in Mexico and Canada. In addition, 
there are unique operational challenges in this environment due to the 
length of the trains (up to 2 miles), the distance required to stop 
moving trains, and the difficulties in separating alarming cars for 
further examination. Furthermore, DHS officials told us that rail 
companies resist doing things that might slow down rail traffic and 
typically own the land where DHS would need to establish stations for 
primary and secondary screening. Moreover, DHS officials said that it 
takes time to develop the necessary close cooperation with officials 
in Mexico and Canada and that an effective solution would require 
scanning of at least some rail traffic on Mexican or Canadian soil, 
before a train enters the United States. As a result, DHS is only in 
the early stages of developing the procedures and technology to 
feasibly scan international rail traffic. DHS is currently undertaking 
an International Rail Threat and Gap Study to determine the most 
promising radiation detection approach. DHS officials also told us 
that implementing the results of this study is subject to the 
availability of adequate funding. 

International Air Cargo and Commercial Aviation: 

DHS is in the early stages of addressing the challenges of scanning 
for radioactive materials presented by air cargo and commercial 
aviation. At present DHS is scanning for radioactive materials at 
certain major international airports in the United States, and has 
deployed some of the PVTs in its plans. It plans to deploy more PVTs 
by the end of 2011. 

International Air Cargo. At present, DHS officials are developing 
plans to increase their capacity to scan for radioactive materials in 
international air cargo conveyed on commercial airlines. DHS officials 
stated that their experience scanning air cargo at a few major 
international airports in the United States has helped them develop 
scanning procedures and inform current and future deployment 
strategies for both fixed and mobile radiation detection equipment. 
However, these officials told us that scanning air cargo planes is a 
challenge because of the lack of natural choke points in airports 
where fixed detection equipment could be deployed. They believe that 
further operational experience and research is necessary before they 
can develop practicable mobile scanning strategies and procedures. 
Until solutions to these challenges can be found, DHS's goal of 
scanning 99 percent of air cargo at 33 international airports by 2014 
is currently on hold. According to DHS officials, whatever scanning 
for radioactive materials occurs at these 33 airports is currently 
conducted with hand-held detectors. 

International Commercial Aviation. As part of a pilot program, DHS is 
developing plans to effectively scan commercial aviation aircraft, 
passengers, and baggage for radioactive materials. 

DHS's Efforts to Prevent Smuggling of Nuclear and Radiological 
Materials into the United States via the Gaps DNDO Identified Are 
Still in the Early Stages of Development: 

DHS efforts to prevent the smuggling of nuclear and radiological 
materials into the United States through the critical gaps DNDO 
identified--land border areas between ports of entry, international 
general aviation, and small maritime craft--remain largely 
developmental. These pathways are important because dangerous 
quantities of nuclear and radiological material can be small and 
portable enough to be carried across land borders by vehicles or 
pedestrians, on most private aircraft, or by small maritime craft. 

In addition, these pathways are challenging because of their size, 
volume of traffic, and the difficulty of deploying available 
radiological and nuclear detection capabilities and technologies. For 
example, the United States has more than 6,000 miles of land border 
with many locations outside of established ports of entry where people 
and vehicles can enter the United States. In the maritime environment, 
a Coast Guard risk assessment revealed that small boats pose a greater 
threat for nuclear smuggling than shipping containers. There are at 
least 13 million registered domestic pleasure craft in the United 
States and 110,000 commercial fishing vessels. These small boats have 
traditionally been used to smuggle drugs and people but could be used 
to smuggle nuclear or radiological material. 

DHS's actions to address these gaps consist primarily of efforts to 
develop, test, and deploy current generation or newly developed 
radiation detection equipment; conduct studies or analyses to identify 
and address particular threats or gaps; develop new procedures to 
guide scanning for radiation in pathways where no scanning had 
occurred before; and develop and learn from pilot programs. 

Land Border Areas between Ports of Entry: 

DHS is taking a number of steps it believes will improve its odds of 
deterring or detecting attempts to smuggle nuclear or radiological 
materials across the more than 6,000 miles of land border susceptible 
to illegal crossings by people and vehicles into the United States. 
Specifically, according to DHS officials, the department is procuring 
more current generation mobile radiation detection technology, seeking 
new technology, and further studying gaps in the detection 
architecture and the threat they pose. These efforts are, however, not 
yet complete and in some cases are behind schedule. For example, DHS 
is currently working to equip Border Patrol officers responsible for 
patrolling the U.S. borders with Canada and Mexico between ports of 
entry with current generation portable radiological and nuclear 
detection equipment--specifically, personal radiation detectors (PRD) 
and RIIDs. Portability is critical to strengthening radiation 
detection efforts, according to DHS officials, because it expands 
border patrol agents' ability to detect a potential radiological 
threat beyond fixed ports of entry. According to its deployment plan, 
DHS planned to buy a certain number of PRDs and RIIDs each fiscal year 
from 2008 through 2011 to complete acquisition by 2012. However, the 
department has fallen short of these targets, citing a lack of funds. 

International General Aviation: 

According to officials, DHS has undertaken some initiatives to scan 
private aircraft entering the United States as international general 
aviation. Since December 2007, DHS has been scanning 100 percent of 
arriving international general aviation aircraft (approximately 400 
flights per day) with a standard hand-held RIID for nuclear and 
radiological material. DHS depends on the aircraft operators to obey 
the law by either arriving in the United States only at an 
international airport--which are all equipped with scanning 
capability--or departing for the United States from one of four 
overseas airports where such aircraft can be scanned before departure. 
Accordingly, DHS has already initiated studies to help it address this 
challenge and plans, according to officials, to initiate further 
studies in 2011. Specifically, among other things, DHS plans to update 
its analysis of pre-clearance scanning capabilities at airports 
overseas and evaluate the feasibility of expanding the number of 
overseas airports with scanning capabilities. It also plans to study 
the characteristics of aircraft that do not comply with U.S. scanning 
requirements and develop interim surveillance options to enhance DHS 
capabilities and mitigation strategies to detect and interdict these 
aircraft. 

Small Maritime Craft: 

A Coast Guard analysis revealed that small boats pose a greater threat 
than shipping containers for nuclear smuggling.[Footnote 8] These 
small boats, which include maritime craft less than 300 gross tons, 
number in the millions. DHS has developed and tested equipment for 
detecting nuclear material on small maritime vessels. However, efforts 
to use this equipment in a port area have been limited to pilot 
programs. Whereas initiatives to combat smuggling at land border areas 
between established ports of entry and through aviation routes are 
being integrated into already existing CBP screening operations, 
initiatives in the maritime environment require DHS to acquire and 
test new equipment and procedures with the Coast Guard and local law 
enforcement agencies. DHS is currently conducting 3-year pilot 
programs in Puget Sound, Washington, and San Diego, California, to 
design, field test, and evaluate equipment and is working with CBP, 
the Coast Guard, state, local, tribal officials, and others as they 
develop procedures for screening. These pilot programs are scheduled 
to end in 2010, when DHS will decide the future path of screening of 
small vessels for nuclear and radiological materials. According to DHS 
officials, initial feedback from federal, state, and local officials 
involved in the pilot programs has been positive. 

DHS hopes to sustain the capabilities created through the pilot 
programs via federal grants to state and local authorities through the 
port security grant program.[Footnote 9] By working with state and 
local authorities in Puget Sound and San Diego since 2007, DHS hopes 
that equipment and procedures can be developed that could be 
transferred to other ports and other waterways and sustained with 
federal grants. DHS's goal is to build some capacity for radiation 
detection in all small and large ports so that federal, state and 
local law enforcement has the capacity for, at the least, random 
searches to keep would-be smugglers guessing, thereby offering some 
measure of deterrence to nuclear and radiological smuggling in this 
pathway. 

According to DHS officials, the Puget Sound and San Diego pilot 
programs have been useful for assessing and developing technologies to 
address the specific challenges of nuclear and radiological detection 
in a maritime environment. DHS expects its testing of existing 
commercial and government off-the-shelf boat-mounted sensors to 
conclude in the summer of 2010 and, depending on the results, will 
either move forward with acquisition of this technology for future 
deployment or initiate a program to develop new technology to meet 
this need. According to officials, DHS also plans to complete or 
initiate a number of studies to analyze options for underwater 
detection and offshore secondary screening of nuclear and radiological 
materials and study the existing detection architecture of inland 
waterways. DHS also plans to conduct a top-down analysis of sea ports 
of entry to assess the effectiveness of existing and proposed nuclear 
and radiological detection architectures. 

DHS Has Not Yet Completed a Strategic Plan for the Global Nuclear 
Detection Architecture: 

DHS does not yet have a strategic plan for the global nuclear 
detection architecture, but DHS officials told us they began working 
on a strategic plan earlier this year and expect to complete it by the 
fall of 2010--2 years after we last recommended such a plan--and more 
than 7 years after we first identified the need for comprehensive plan 
in October 2002. In our view, DHS might have made greater progress 
towards completing the architecture if it had a strategic plan. 

DHS Officials Are Working on a Strategic Plan: 

According to DHS officials, DNDO is in the process of establishing a 
steering committee to guide and oversee the development of the 
strategic plan with interagency partners including the Departments of 
Defense, Energy, Justice, and State, the Nuclear Regulatory 
Commission, and the Office of the Director of National Intelligence. 
DHS officials attributed the delay in developing a strategic plan to a 
number of factors, including DNDO's initial focus on installing 
radiation detection equipment at ports of entry at land border 
crossings and major seaports in response to the requirements of the 
SAFE Port Act, which set a number of benchmarks and deadlines for 
scanning cargo entering the United States. DHS officials also cited 
the challenges and difficult decisions involved in addressing gaps in 
the areas between ports of entry. 

In addition, DHS officials said that they recognized that increasing 
detection capabilities in one area of the architecture could simply 
lead a potential smuggler of nuclear or radiological materials to use 
another pathway into the United States. In developing the strategic 
plan, they are considering ways to cover a greater range of potential 
pathways into the United States. Drawing lessons from the tactics 
police use to catch speeding motorists, DHS officials have concluded 
that the most effective way to deter and make more difficult the 
smuggling of nuclear and radiological materials into the United States 
is to develop more agile and randomly deployed detection capabilities, 
similar to how local and state police deploy officers and speed 
detection equipment randomly to deter drivers from traveling over the 
lawful speed limit. DHS officials described this approach as a shift 
from "detection to prevention." This approach is consistent with the 
basic design principles developed by DHS, as part of a multinational 
collaborative process, to guide countries' efforts to prevent nuclear 
terrorism. DHS identified several attributes of an effective nuclear 
detection architecture including, among other things, the capacity to 
balance risk reduction and cost effectiveness, rely on multiple layers 
of protection, adapt and evolve over time to changing threats, be 
unpredictable to the adversary, augment the effectiveness of radiation 
detection technologies with the use of intelligence and other 
information sources that could help law enforcement select certain 
targets for scrutiny, and be integrated within a larger national and 
international security framework. 

DHS Might Have Completed the Architecture Sooner If It Had a Strategic 
Plan: 

In our view, the lack of a strategic plan has limited DNDO's efforts 
to develop a global nuclear detection architecture. Strategic planning 
is a way to respond to this governmentwide problem on a governmentwide 
scale. Our past work on crosscutting issues suggests that 
governmentwide strategic planning can integrate activities that span a 
wide array of federal, state, and local entities.[Footnote 10] 
Although each agency with a role in combating nuclear smuggling has 
its own planning documents, an overarching strategic plan is needed to 
guide these efforts to address the gaps and move to a more 
comprehensive global nuclear detection strategy. In 2005, we reported 
that strategic plans should clearly define objectives to be 
accomplished, identify the roles and responsibilities for meeting each 
objective, ensure that the funding necessary to achieve the objectives 
is available, and employ monitoring mechanisms to determine progress 
and identify needed improvements.[Footnote 11] For example, such a 
plan would define how DNDO would monitor the goal of detecting the 
movement of radiological and nuclear materials through potential 
smuggling routes, such as small maritime craft or land border areas in 
between ports of entry. Moreover, this plan would include agreed-upon 
processes and procedures to guide the improvement of the efforts to 
combat nuclear smuggling and coordinate the activities of the 
participating federal agencies. DNDO's 4-year effort to develop ASPs 
is an example of the consequences of not having a strategic plan and 
not reaching consensus on such a strategic plan with other federal 
agency partners. We believe the proposed deployment of ASPs distracted 
DNDO from its mission to fully deploy a nuclear architecture and close 
the gaps it identified in the architecture. In addition, in 2006 we 
recommended that the decision to deploy ASPs be based on an analysis 
of both the benefits and costs[Footnote 12]--which we later estimated 
at over $2 billion[Footnote 13]--and a determination of whether any 
additional detection capability provided by the ASP is worth its 
additional cost. DNDO has proceeded with ASP testing without fully 
completing such an analysis. Furthermore, DNDO focused its ASP 
deployment efforts on replacing components of the architecture with 
ASPs where a detection system was already in place--established ports 
of entry that were using PVTs and RIIDs--and shifting its focus away 
from finishing the PVT deployments at ports of entry and closing the 
gaps it identified in the architecture. 

Similarly, in our view, had a strategic plan to complete the global 
nuclear detection architecture been in place, DHS may have been less 
likely to expend time and resources on ASPs when a radiation detection 
system was already in place at ports of entry but not at other 
potential pathways into the United States. A recent development that 
complicates the future deployments of radiation detection equipment is 
that both PVTs and ASPs require helium-3, which was recently found to 
be in short supply.[Footnote 14] According to DHS officials, if an 
alternative to helium-3 is not found by late 2011, further deployments 
of PVTs planned for the southern land border and at seaports may be 
delayed. We are currently conducting work on the helium-3 shortage-- 
describing the federal government's current priority for how the 
limited supply of helium-3 will be allocated and assessing, among 
other things, what alternative technologies are currently available or 
in development that could replace helium-3. We plan to issue a report 
later this year. 

In addition to lacking a strategic plan, we also found that DHS did 
not use the Joint Annual Interagency Review of the Global Nuclear 
Detection Architecture to effectively coordinate U.S. government 
nuclear detection priorities. In July 2007, Congress passed the 
Implementing Recommendations of the 9/11 Commission Act of 2007, 
[Footnote 15] which required DHS to collaborate with the Departments 
of Defense, Energy, Justice, and State as well as the Director of 
National Intelligence on an annual report assessing federal agencies' 
involvement, support, and participation in the development, revision, 
and implementation of the global nuclear detection architecture. In 
January 2009, we recommended that DHS use this review to guide future 
strategic efforts to combat nuclear smuggling, including analyzing 
overall budget allocations to determine whether governmentwide 
resources clearly align with identified priorities to maximize results 
and whether there is duplication of effort across agencies.[Footnote 
16] DHS did not directly comment on our recommendation and did not use 
the most recent Joint Annual Interagency Review it issued in January 
2010 as a tool to analyze nuclear detection budgets across the 
agencies with which it is required to collaborate on the report. 
Specifically, the 2010 report does not describe a process through 
which DHS used the review to guide or modify budget allocations or 
better align resources with identified priorities. While the report 
has been reviewed and approved by DHS and the Departments of Defense, 
Energy, Justice, State, and the Office of the Director of National 
Intelligence, the report does not make clear whether it is used as a 
part of these agencies' programmatic or strategic planning processes. 

In conclusion, DHS is at a crossroads. With such vast land borders, 
coast lines, and air space to protect, addressing the gaps in the 
architecture is, in many respects, a more difficult task than 
preventing the smuggling of nuclear material through ports of entry. 
Now that land border crossings and seaports appear to have become more 
secure through law enforcement and technology, it makes the other gaps 
in the architecture potentially more attractive to would-be smugglers 
and terrorists. At a time of flat or declining federal agency budgets, 
it is especially important that DHS develop a strategic plan for its 
global nuclear detection architecture so that it can articulate its 
priorities in addressing these gaps and allocate resources based on 
those priorities to maximize results. In addition, given the national 
security implications and urgency attached to combating nuclear 
smuggling globally, and that multiple federal agencies are involved, 
we continue to believe that such a plan needs to be established as 
soon as possible. Without an overarching plan that ties together the 
various domestic and international efforts to combat nuclear smuggling 
and clearly describes goals, responsibilities, priorities, resource 
needs, and performance metrics, it is unclear how a strategy will 
evolve or whether it is evolving in the right direction. 

Mr. Chairman, this completes my prepared statement. I would be happy 
to respond to any questions that you or the other Members of the 
committee may have at this time. 

GAO Contact and Staff Acknowledgments: 

For further information about this testimony, please contact me at 
(202) 512-3841 or aloisee@gao.gov. Dr. Timothy Persons (Chief 
Scientist), Ned Woodward (Assistant Director), Joseph Cook, Carol 
Kolarik, Jonathan Kucskar, Alison O'Neill, Kevin Tarmann, and Kiki 
Theodoropoulos made key contributions to this testimony. 

[End of section] 

Footnotes: 

[1] National Security Presidential Directive 43/Homeland Security 
Presidential Directive 14, Domestic Nuclear Detection, April 15, 2005. 
DNDO was established in statute by the Security and Accountability for 
Every Port Act of 2006 (SAFE Port) Act, Pub. L. No. 109-347, § 501 
(codified at 6 U.S.C. §§ 591-596a). 

[2] GAO, Customs Service: Acquisition and Deployment of Radiation 
Detection Equipment, [hyperlink, 
http://www.gao.gov/products/GAO-03-235T] (Washington, D.C.: Oct. 17, 
2002). 

[3] GAO, Nuclear Detection: Preliminary Observations on the Domestic 
Nuclear Detection Office's Efforts to Develop a Global Nuclear 
Detection Architecture, [hyperlink, 
http://www.gao.gov/products/GAO-08-999T] (Washington, D.C.: July 16, 
2008). 

[4] GAO, Nuclear Detection: Domestic Nuclear Detection Office Should 
Improve Planning to Better Address Gaps and Vulnerabilities, 
[hyperlink, http://www.gao.gov/products/GAO-09-257] (Washington, D.C.: 
Jan. 29, 2009). 

[5] CBP conducts primary inspections with radiation detection 
equipment called portal monitors--large stationary detectors through 
which cargo containers and vehicles pass as they enter the United 
States where they are screened for smuggled nuclear or radiological 
material that could be used in an improvised nuclear device or 
radiological dispersal device (a "dirty bomb"). When radiation is 
detected, CBP conducts secondary inspections using a second portal 
monitor to confirm the original alarm and a handheld radioactive 
isotope identification device to identify the radiation's source and 
determine whether it constitutes a threat. 

[6] GAO, Combating Nuclear Smuggling: Additional Actions Needed to 
Ensure Adequate Testing of Next Generation Radiation Detection 
Equipment, [hyperlink, http://www.gao.gov/products/GAO-07-1247T] 
(Washington, D.C.: Sept. 18, 2007). 

[7] [hyperlink, http://www.gao.gov/products/GAO-03-235T]; GAO, 
Combating Nuclear Smuggling: DHS Has Made Progress Deploying Radiation 
Detection Equipment at U.S. Ports-of-Entry, but Concerns Remain, 
[hyperlink, http://www.gao.gov/products/GAO-06-389] (Washington, D.C.: 
Mar. 22, 2006); GAO, Nuclear Detection: Preliminary Observations on 
the Domestic Nuclear Detection Office's Efforts to Develop a Global 
Nuclear Detection Architecture, [hyperlink, 
http://www.gao.gov/products/GAO-08-999T] (Washington, D.C.: July 16, 
2008); and [hyperlink, http://www.gao.gov/products/GAO-09-257]. 

[8] From testimony delivered by Vice Admiral Thad Allen on the role of 
Coast Guard in border and maritime security, Committee on 
Appropriations, Subcommittee on Homeland Security, U.S. Senate, Apr. 
6, 2006. 

[9] The Port Security Grant Program (PSGP), established by the 
Maritime Transportation Security Act of 2002, is one of several DHS 
grant programs focusing on transportation infrastructure security. The 
purpose of the PSGP is to promote sustainable, risk-based efforts to 
protect critical port infrastructure from terrorism, particularly 
attacks using explosives and non-conventional threats that could cause 
major disruption to commerce. In fiscal year 2010, the total amount of 
funds distributed under this grant will be $288 million. 

[10] GAO, A Call For Stewardship: Enhancing the Federal Government's 
Ability to Address Key Fiscal and Other 21st Century Challenges, 
[hyperlink, http://www.gao.gov/products/GAO-08-93SP] (Washington, 
D.C.: Dec. 17, 2007). 

[11] GAO, Managing for Results: Enhancing Agency Use of Performance 
Information for Management Decision Making, [hyperlink, 
http://www.gao.gov/products/GAO-05-927] (Washington, D.C.: Sept. 9, 
2005); GAO, Results-Oriented Government: Practices That Can Help 
Enhance and Sustain Collaboration among Federal Agencies, [hyperlink, 
http://www.gao.gov/products/GAO-06-15] (Washington, D.C.: Oct. 21, 
2005). 

[12] [hyperlink, http://www.gao.gov/products/GAO-06-389]. 

[13] GAO, Combating Nuclear Smuggling: DHS Needs to Consider the Full 
Costs and Complete All Tests Prior to Making a Decision on Whether to 
Purchase Advanced Portal Monitors, [hyperlink, 
http://www.gao.gov/products/GAO-08-1178T] (Washington, D.C.: Sept. 25, 
2008). 

[14] Helium-3 is a by product of the production of tritium, a key 
isotope used in nuclear weapons. With the end of the Cold War the 
production of helium-3 has been reduced significantly. However, since 
September 2001, the demand of helium-3 has increased dramatically 
because radiation portal monitors deployed for homeland security and 
non-proliferation use it for neutron detection; neutrons are emitted 
by special nuclear materials, which can be used to construct a nuclear 
weapon. 

[15] Pub. L. No. 110-53 (2007). 

[16] [hyperlink, http://www.gao.gov/products/GAO-09-257]. 

[End of section] 

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