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OCR Page 1 of 2Originally Processed With FOIA(s):
FOIA Number:
1998-0004-F[1]; 2005-0336-F
S
FOIA
MARKER
This is not a textual record. This is used as an
administrative marker by the George Bush Presidential
Library Staff.
Record Group/Collection:
George H.W. Bush Presidential Records
Collection/Office of Origin: Chief of Staff, White House Office of
Series:
Sununu, John, Files
Subseries:
White House Offices Files
OA/ID Number:
29184
Folder ID Number:
29184-002
Folder Title:
Science and Technology (Bromley) (1991) [2]
Stack:
Row:
Section:
Shelf:
Position:
G
15
25
6
1
THE WHITE HOUSE
Amil2.91
hourth a cary gihe interagency
cheau you etyet,
interin pepart on The Ruwait
Oil fire. - the appendiciane
interesting.
Alan
Dear John:
In case you haven't seen it yet, herewith a
copy of the interagency interim report on
the Kuwait oil fields. The appendices are
interesting.
THE CHIEF of STAFF
has seen
[OA/ID 29184-002]
SCIENCE AND TECH NOLOGY (BROMLEG) FF&Z
1991(2)
Draft
Kuwait
KUWAIT
IRAN
Oil
Fires:
BAHRAIN
Interagency
OMAN
Interim
QATAR
SAUDI
UNITED ARAB SEATRATES 20°
Report
ARABIA
April 2, 1991
KUWAIT OIL FIRES
INTERAGENCY INTERIM REPORT
I.
SUMMARY
More than 500 oil well, storage tank and refinery, and facility fires are currently raging in Kuwait and
each day produce an enormous amount of smoke and other pollutants. The quantity and character of
the smoke plumes are not yet certain, and the fires are expected to continue for some period. The
fires originate in seven oil fields, located both north and south of Kuwait City, with the majority
centered in the AI Burgan oil field south of the Kuwait City airport. The fires may represent one of the
most extraordinary manmade environmental disasters in recorded history.
In response to this situation, the Saudi Government requested U.S. technical assistance on the public
health and environmental impact of the fires. The U.S. Embassy in Saudi Arabia concurred in this
request, and voiced its additional concerns about the health effects of the fires on the hundreds of
thousands of U.S. troops in the region as well as the thousands of American citizens residing in Saudi
Arabia and the other Gulf countries. Similar concerns were also expressed in Kuwait. An Interagency
Air Assessment Team consisting of representatives from the Environmental Protection Agency, the
National Oceanic and Atmospheric Administration, and the Department of Health and Human Services
was formed and deployed to the Persian Gulf area. In country, this team was supplemented by
representatives of the United States Coast Guard, the Department of Defense, and the Department of
Energy.
The specific mission of the team was to assess the conditions through air sampling and monitoring in
oil fields and other areas to determine the effect on public health; to review the health infrastructure;
to determine the capability of the region to deal with the health threat through air monitoring and
appropriate corrective action; and to provide technical assistance. Further, the team was to provide
specific recommendation for follow-up action.
Meteorological conditions over the past two months have tended to transport the smoke plume toward
the southeast, with periodic excursions toward the northeast. March through July are relatively windy
months; there are normally 30 days of very strong winds from the northwest in this period, which
produce sandstorms and rapidly ventilate the smoke. From August to October, the incidence of strong
winds should drop sharply. The plume is generally below about 12,000 feet. As the summer
progresses, it is possible that the height of the plume will increase and that it will then be evident to
greater distances.
Emissions from oil fires may have the potential of causing health effects of both an acute and chronic
nature, although there is considerable uncertainty as to the extent of the threat. Chemicals such as
sulfur dioxide and hydrogen sulfide as well as carbon monoxide and polycyclic aromatic hydrocarbons
are often found along with particulate matter in oil fires. While only a limited assessment is possible
at this time, the Team did not detect such chemicals in any significant quantity; also, preliminary
analysis of the substantial amount of particulate matter did not reveal any chemicals at levels of
concern. However, this suggests that the locations where sampling and monitoring were performed
and the protocol used were not able to detect the high levels of pollutant except for particulates, and
more data on particulates and potential toxic agents need to be collected to characterize the inhalable
particulates, determine the health consequences, and develop a response for the affected population.
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1
The host nation governments also provided the Team with an abundance of preexisting air monitoring
information covering the past several years in Saudi Arabia, Kuwait, and Bahrain. These data provide
a useful baseline on limited parameters for comparing the conditions that exist and may evolve during
the next several months. The Team concurred with the Saudi Government's view that the considerable
Saudi public and private sector competence in air monitoring would need to be supplemented with
support and technical assistance. This situation is even more acute in Kuwait City due to the lack of
power and to the disruption of the governmental and scientific infrastructure. The Team considered
it of critical importance that additional technical assistance be provided to the countries.
There is need to consider the overall problem from several perspectives so as to ensure economy as
well as success. First, because high levels of particulates were found in the air, and prolonged
exposure to particulate matter may contribute to respiratory discomfort and perhaps long-term or
permanent respiratory disorder, it will be necessary to find out what is in the plume and how it varies
over time and distance. Second, we should assess the immediate and long-term human health risk.
Third, we should quantify effects on the environment, especially on crops and climate.
II.
TEAM'S ACTIVITIES AND FINDINGS
With the assistance of the Saudi and Kuwaiti Governments, the U.S. Interagency Air Assessment Team
has been conducting a reconnaissance survey of the fire plumes and their effects in Kuwait and Saudi
Arabia since March 10, 1991. The primary objective of the Team was to obtain preliminary, short-term
data on the emissions from the smoke emanating from the oil well fires at a variety of locations, in
order to:
1.
Determine if there is an acute health threat associated with the Hydrogen Sulfide (H₂S)
and Sulfur Dioxide (SO₂) and particulates, three toxic pollutants that might be emitted
from burning oil wells;
2.
Identify and quantify the gaseous and particulate byproducts being produced from the
burning oil wells; and
3.
Determine if the materials associated with these fires are affecting areas where
American citizens are located.
4.
Assess the potential extent of the health effects related to the emissions from the fires
and the status of the Kuwaiti and Saudi health infrastructure.
Based on these objectives, limited, real-time data was obtained directly from the Kuwait oil fields, as
well as from Kuwait and Saudi Arabia locations where embassy officials, troops, and citizens work and
reside. Additionally, the Team conducted a number of interviews with health officials to evaluate the
extent of acute respiratory problems related to smoke exposure. While only a cursory assessment is
possible at this point, some data obtained by the team were encouraging. The preliminary findings are
as follows:
1.
Limited sampling did not reveal the existence of high concentrations of sulfur dioxide
or hydrogen sulfide near the burning wells or in population areas in the path of the oil
well emissions;
2.
High levels of particulate were found in the air;
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2
3.
The results of the current monitoring findings and health interviews with medical
personnel in the affected areas suggest that at the present time susceptible
subpopulations, such as individuals with asthma and chronic obstructive lung disease,
may experience exacerbation of their symptoms. Special health concerns, warnings,
advisories, and precautions are clearly warranted for these individuals. However, this
does not appear to be life threatening under current exposure conditions. However,
if meteorological conditions change, i.e., poor air mixing or plume touchdown, there
could be adverse health effects; and,
4.
The long-term effects on health are not readily ascertainable at this time due to
insufficient data on the populations exposed, the composition of the smoke plume, the
impact of oil pools, and long-term meteorological patterns. The Kuwaiti and Saudi
health communities have historically focused on communicable diseases from a public
health standpoint and do not possess the necessary logistical capabilities for
responding to environmental health issues. However, both the Kuwaiti and Saudi
health communities have expressed great interest in obtaining training and support
from the US medical community that can be continued by themselves in future years.
Aggravating the problem is the severe damage done to the scientific infrastructure of
Kuwait thus limiting the current in-country analytic capabilities. Any response by the
US would have to include both training and equipment.
The Team has stressed, however, that their observations represent only a preliminary assessment and
that considerable follow-up will be necessary to evaluate definitively the nature and magnitude of the
human health, ecological, and atmospheric effects of the oil fires.
III.
PROPOSED PROGRAM
The local populations are being exposed to an increased health risk, the magnitude of which cannot
be estimated with any degree of certainty without further measurements and surveys. The extent to
which conditions may worsen needs to be understood and a forecast capability developed. Without
such measurements and assessment, and development of a predictive capability, the regional
population remains exposed to an uncertain risk, and reconstruction of the area may be impeded.
Moreover, without such input, an accurate and defensible quantification of environmental effects will
not be possible.
In addition to providing direct answers to questions regarding the effects of the smoke plumes on the
atmospheric environment, intensive studies of the plumes will accelerate progress in understanding
manmade effects on regional and global air quality, meteorology, and climate. Because the expected
changes in air chemistry, solar radiation, and cloud microstructure are so large, observations of these
processes could circumvent the need for many years of study directed at much lesser phenomena.
The program proposed below is comprised of three primary elements: human health surveillance and
risk assessment, air monitoring, and development of a forecast capability. These elements will be
closely linked to achieve the goals of understanding and predicting the degree of human health risk and
the effects on atmospheric processes.
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3
1.
Air Monitoring
The objective of the air monitoring program is to collect the necessary data to determine the nature
and concentration of pollutants associated with the fires, and demonstrate the recovery of the
environment as the fires are extinguished.
The development and deployment of an integrated monitoring network will serve several interrelated
purposes. It will assure data consistency throughout the region. It will provide better data to assess
the immediate health risk and potential for long term risks. It will be used to initiate, test, and refine
forecast models discussed later in this plan, and thus greatly assist in the development of location and
condition specific alerts -- assisting in issuing special advisories for populations at risk under unique
conditions. Lastly, it will provide a better basis for scientific understanding and knowledge of the
important regional and international issues and will assist in assessing possible extended consequences
of the fires.
The U.S. Interagency Air Assessment Team is working with the Saudi Arabian Meteorology and
Environmental Protection Agency (MEPA), Saudi ARAMCO, and King Fahd University of Petroleum and
Minerals to develop an air monitoring plan for the Gulf Region that will provide the air monitoring data
to assess the impact of the Kuwaiti fires in Saudi Arabia. While focused primarily on the needs of
Saudi Arabia, the plan forms the general basis for a regional network that should meet the needs of
other Gulf nations as well.
The following activities are proposed in cooperation with and support of the host governments:
immediate steps would be taken to collect and analyze meteorological observations and
forecasts, record visual observations of the smoke plume, and review existing
monitoring data. Plume observations via satellite would be obtained daily,
supplemented by periodic on-scene aerial transects designed to characterize the overall
geometry of the plume.
A ground-based sampling network of portable equipment would be installed by EPA and
others at approximately 15-20 locations to measure particulate matter less than 10
microns in diameter (the particle size most likely to penetrate deeply into the lungs).
The ratio of the less than 10 micron particles to total particulate load would be
established. Limited organic analysis would be undertaken.
Measurements of carbon monoxide, carbon dioxide, methane, hydrogen sulfide, sulfur
dioxide, particle size distribution, elemental and organic carbon, metals, polycyclic
aromatic hydrocarbons, and acid aerosols would be obtained close to the fires by
NASA and NIST. These measurements should attempt to characterize and categorize
emissions from several specific wells.
Specially equipped aircraft from the University of Washington (April 15 to May 15),
NCAR (May 1 to June 1), and NOAA (July 1 to August 1) would be deployed to
measure downwind plume composition and dispersion, radiative properties and climatic
effects, and effects on clouds and precipitation. On the basis of the initial aircraft
results, a longer-term sampling program would be designed to monitor the relaxation
of the atmospheric environment as the fires are extinguished.
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4
Six additional comprehensive air quality monitoring stations would be established along
the general axis of the plume from Kuwait City to Saudi Arabia to collect data on
particulates, as well as on the organic and inorganic constituents of the plume.
Meteorological stations would be co-located at as many as possible of the selected
monitoring sites. Data would be collected on wind, temperature, humidity, direct and
diffuse radiation, soil temperature, and precipitation. Ten precipitation monitoring
stations operated by WMO would be upgraded to measure departures in precipitation
chemistry and restabilization to normal levels.
A data and information system would be designed to provide world-wide access to
data of all types related to the fires. High speed data transmission capability would be
established to enable image, graphics, and text exchange among participants in the
monitoring, forecast, and health elements of the program. In the short-term a
temporary archive would be developed to avoid loss of key data sets.
2.
Development of a Forecast Capability
The objective of this activity is to develop an early warning advisory system for the Gulf and downwind
regions. The system would forecast the trajectory of plumes created by the fires and compute the
atmospheric concentrations of several constituents of known human health and potential environmental
impact.
Mathematical models of the fires and their effects are being developed by institutions in Saudi Arabia
and the United States to assess the impact of the fires. The models detail the combustion process
associated with each well, and predict plume rise, chemical transformations, transport and dispersion,
and particle deposition. These models are in turn linked to other algorithms and databases to predict
the impact of the plume on human health, and the local and distant environment (including effects on
crops).
A number of activities would be undertaken to complete the development of a forecast system:
Short-term meteorological forecasts would be used immediately to predict the
orientation and general concentration of the smoke plume throughout the region.
Existing models in the U.S., Saudi Arabia, and elsewhere would be tested through air
quality measurements obtained through the monitoring program described in the
preceding section. As testing is completed, the models would be used to adjust the
location of portable monitoring stations for optimal sampling and provide improved
forecasts of plume characteristics.
Selected models, when tested, would be assembled into a single computer system
linked to weather forecast models available through NOAA's National Climatic Data
Center. The system would form the basis of an early warning system with terminals
into the system available both in the United States as well as from the Gulf region.
At the conclusion of model development and testing, training and equipment would be
provided to allow the modeling capability to be fully operated by appropriate agencies
in the Gulf region.
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5
3.
Human Health Surveillance and Risk Assessment
The objectives of this activity are to assess initial data obtained by the U.S. Interagency Air
Assessment Team, to set up the needed infrastructure, and to conduct medical surveillance,
epidemiological studies, and clinical field studies for the purpose of examining specific health endpoints
in order to ascertain whether there are short-term and/or long-term trends in morbidity and mortality
associated with exposure to the oil smoke plumes and deposition.
Developing plans for and conducting a cross-disciplinary approach to human health risk assessment
and health advisories is a difficult, complex and time-consuming task. The plan presented below can
proceed only after accomplishing a coordinated interagency evaluation and assessment of the EPA
monitoring data and other information. At that time, additional monitoring and modeling may be
required. On that basis, the scope of effort, the type and number of health personnel both here and
abroad, equipment, and other items cannot be identified in any detail. However, continued
coordination and collaboration with the DOD and the Kuwaiti and Saudi health authorities is necessary
to maintain established information sharing. Continued information sharing will aid in the development
of baseline data for a complete human health risk assessment. In addition, this can help provide
Kuwait with some important needed assistance in reestablishing their medical and health care
infrastructure.
The following tasks need immediate attention:
Health advisories should be reviewed and updated for use by military and non-military
personnel based on an assessment of the U.S. Interagency Air Assessment Team data
and observations.
Interim preventive measures should be identified and initiated including, but not limited
to, the use of dust masks and limiting exercise during periods of severe smoke.
Medical facilities should be alerted to the potential increased frequency of asthma
attacks and eye irritations and ensure adequate supplies of appropriate medications.
Protocol should be established to alert military, indigenous, and other non-military
transient populations of potential health risks, particularly for high risk populations such
as asthmatics, people with heart disease or chronic obstructive pulmonary disease,
children, and pregnant women.
A plan should be developed to collect needed medical and demographic information on
affected populations including health examinations and a permanent archive of service
records for all U.S. personnel stationed in the Gulf. These records will be vital in order
to answer future questions on the health impact of U.S. personnel serving in the Gulf.
Host governments should be assisted, as requested, in baseline studies of affected
populations.
Develop plans for conducting medium- and long-term epidemiological and clinical
studies, and establishing medical surveillance systems.
Establish criteria for assessing the effectiveness of an early warning system to protect
the U.S. and civilian personnel. Based on the monitoring system established by the
host countries, an early warning health advisory system should be established.
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6
These efforts should promptly follow:
Non-plume and plume samples for short-term in-vitro and in-vivo toxicity and
mutagenicity testing and dose response assessment should be collected.
Acute and chronic health risks based on integrating information from exposure
assessments, epidemiological/clinical studies, and in-vitro and in-vivo toxicity studies
must be assessed.
Assess the impact of oil pooling and combustion deposition on potential exposure
pathways.
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7
4.
Budget
Note: All activities itemized in this budget would be conducted in coordination and collaboration with the competent host country
authorities. Progress in assessing the health effects of the oil fires will be regularly reviewed with the host governments.
Phase I: First three months
Phase II: Second three months
Phase I
Phase II
Health Surveillance and
Risk Assessment, including:
$500,000
$1,500,000
Health Surveillance
Short-term In-vivo/In-vitro Studies
Epidemiological/Clinical Field Studies
Health Risk Assessment Database
Health Advisories
Air Monitoring
Aerial Measurements
NASA
100,000
UW
850,000
350,000
NCAR
950,000
350,000
NOAA
500,000
300,000
DOE
500,000
Ground-based Measurements
Initial PM-10 Sampling
55,000
55,000
Meteorological stations
375,000
90,000
Full network implementation
and analysis
400,000
400,000
Air Monitoring Subt& a 30,000
2,045,000
Forecast Capability
Model development
150,000
100,000
System integration
125,000
90,000
Data acquisition
50,000
50,000
Model operation
150,000
180,000
Subtotal
475,000
420,000
Data and Information Management
375,000
150,000
Program Management and Administration
300,000
200,000
Total Project Cost
$4,580,000
$3,615,000
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8
IV.
INTERNATIONAL COORDINATION
The U.S. Interagency Air Assessment Team currently working in the Gulf region has undertaken several
first steps to coordinate planning with the governments of Saudi Arabia, Kuwait, and Bahrain. To
achieve the objectives of this plan, several further steps toward international coordination are
necessary:
Arrangements should be made with the government of Kuwait to complete the
reactivation of the three air monitoring stations which were operating before the war.
These stations will be critical to obtaining key observations near the source of the fires.
The British Meteorological Office is currently conducting long-range sampling of the fire
plume by aircraft. Coordination of data exchange and research plans between
programs should be arranged through WMO.
WMO should also be requested to arrange for collaboration of modeling efforts with
Canadian and British scientists who work on similar programs.
Collaboration is needed with Kuwaiti and Saudi health authorities to assess the
effectiveness of an early warning system to limit or reduce air pollution-related
mortality and morbidity, and to monitor trends in respiratory disease.
The design and conduct of short-and long-term epidemiological and clinical studies
must be integrated between Kuwaiti, WHO, and other countries providing assistance.
To the extent feasible, and, when requested, U.S. agencies should work with
multinational organizations to rebuild the public health infrastructure in Kuwait.
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9
APPENDIX A
AIR SAMPLING AND MONITORING
The initial air sampling and monitoring program conducted by the U.S. Interagency Air Assessment
Team in Kuwait and Saudi Arabia had the following objectives:
1. Determine if there is an acute health threat associated with the Hydrogen Sulfide (H2S) and
Sulfur Dioxide (SO2) gases being emitted from the burning oil wells.
This objective was accomplished by collecting Real Time Measurements (i.e. instantaneous readings)
using portable instruments for the following parameters: H2S, SO2, oxygen, and total particulate. These
measurements were collected at 13 locations in Kuwait and Saudi Arabia, U.S. Embassies in Kuwait and
Riyadh, MEPA Dhahran, at five oil well fields, and at various locations near the oil fields in Kuwait. The
results from the March 13-20 monitoring are summarized in Table 2.
The highest readings were recorded from measurements taken in the smoke plumes in the oil fields.
The results from this monitoring did not indicate an acute health threat. However, if conditions change, (i.e.,
fires are extinguished without capping, allowing high levels of gases) an acute threat near the wells may
occur.
The highest levels observed were: particulate 5.4 mg/m3, VOCs 2.5 ppm (adjacent to large pools
of oil), H2S 42 ppb, and SO2 2 ppm. It should be noted that the detection limit for the SO2 monitor is 1-2
ppm. A different SO2 monitor with a detection limit 0.1 ppm did not indicate SO2. Also, the field personnel
were unable to detect any sulfur odors at any of the locations. Therefore, the SO2 levels of 1-2 ppm should
be used with caution.
The only elevated levels observed in the monitoring conducted in the population areas were for
particulates. A reading of 480 ug/m³ was obtained at MEPA in Dhahran, Saudi Arabia. Based on field
observation this reading was probably a combination of smoke from the fires and sand. Baseline particulate
levels due to blowing sand in Saudi Arabia and Kuwait range from 200-3000 ug/m³.
Further sampling and monitoring occurred from 3/24 - 3/27. These results are also attached. The
results from this monitoring are similar the previous monitoring results. In general, the particulate
concentrations at ground level in the oil fields were lower than in the downwind areas outside the fields,
except when in the direct path of a ground level plume. The downwind locations most heavily affected vary,
depending on wind speed, temperature, humidity, and other diurnal factors.
The real time particulate readings during this phase are 15 and 20 minute averages. The highest
reading occurred at the Ahmadi Hospital, with a 20 minute average reading of 0.935 mg/m³ with a single
highest reading of 1.16 mg/m³. Other successive 20 minute averages taken at this location display the
variation in particulate levels at the same location, as conditions such as wind direction change.
2. The second objective was to identify and quantify the gaseous and particulate byproducts that
are associated with the burning oil wells.
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A-1
This objective has partially been accomplished. Samples from 10 locations have been analyzed by
ERT's laboratory in the U.S. The air samples were collected for the following parameters at all locations:
volatile organic (VOCs), polycyclic aromatic hydrocarbons (PAHs i.e naphthalene, benzo[a]pyrene), heavy
metals, SO2, and inorganic acids (i.e. sulfuric, nitric, etc.). A limited number of samples were collected for
H2S, formaldehyde, CO, and total nuisance dust. For specific findings relevant to these samples see the
section entitled "Air Sampling Results."
3. The third objective was to determine if the materials associated with the fire were effecting areas
where American citizens were located.
This objective will partially be accomplished by reviewing the data from the samples taken at MEPA
Dhahran, Saudi Arabia, U.S. Embassies in Kuwait and Riyadh, Camp Freedom Kuwait, and Port Shuaybah,
Kuwait, and reviewing the air monitoring data being collected by MEPA and ARAMCO in Saudi Arabia air
monitoring stations and sulfur dioxide data taken at temporary hospital locations in Kuwait City.
In order to complete this objective in a sound scientific manner, sampling for PM₁₀ particulate (i.e.
particulate less than 10 microns in size), which are the respirable particulate, and samples from the plume
above ground level should be taken. Also, the air monitoring network proposed by the U.S. Interagency Air
Assessment Team should be implemented.
AIR SAMPLING RESULTS:
The results from the air samples collected for sulfur dioxide, volatile organics, and inorganic acids
from 3/13 3/20 in Kuwait and Saudi Arabia confirmed the real time measurements and sampling and
analysis performed by the Kuwaitis and the Saudis. These results confirmed the conclusion of the U.S.
Interagency Air Assessment Team that the primary hazards from the oil well fire is with the particulate matter.
The highest level of sulfur dioxide (0.68 ppm) was detected in the smoke plume of the Burgan Oil
Field. This level is above the EPA 24 hour (0.14 ppm) and 3 hour (0.5 ppm) limit. None of the sulfur dioxide
samples collected in populated areas exceeded the EPA air quality limits.
The organic vapor analysis showed that compounds associated with petroleum (i.e. benzene,
toluene, and aliphatic hydrocarbons such as n-heptane (n-C7)) were detected. The highest levels (i.e. 10-20
ppb level) were detected in the smoke plume in the oil fields and a grab (SUMMA) sample collected at
ground level near a pool of oil in the Sabiriyah well field. The inorganic acid analysis showed low ppb levels
for both sulfuric and nitric acid. Based on this limited data, the sulfur dioxide and nitrous oxide that may
be byproducts from the burning of the oil are not being formed in large amounts.
The results from the particulate analysis for polycyclic aromatic hydrocarbons (PAHs) and heavy
metals showed very low levels of both parameters in the samples collected in the populated areas and in
the oil fields. The only metals detected were those associated with materials found in the sand particles (i.e.
sodium, aluminum, magnesium, etc.).
Based on these limited number of samples, the major hazard associated with the oil well fires seems
to be the particulate matter being emitted. The monitoring and sampling program discussed in the Air
Monitoring Strategy Plan should help further define the hazards associated with the particulates.
The complete results from the sampling are summarized in the attached exhibits. Only the
compounds detected are listed.
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A-2
PARAMETERS:
The air samples collected at the oil well fields, Camp Freedom, MEPA Dhahran, Saudi Arabia, and
U.S. Embassies in Kuwait and Riyadh, Saudi Arabia were analyzed for the following parameters:
PAHs:
Naphthalene,2-Methylnaphthalene,1-Methynapthlalene,Bipheny,2,6-Dimethylnaphthalene,
Acenaphthylene, Acenapthene, Dibenzofuran, Fluorene, Phenanthrene, Anthracene,
Carbazole, Fluoranthene, Pyrene, Benzo[a]anthracene, Chrysene, Benzo[b]fluoranthene,
Benzo[k]flouranthene, Benzo[e]pyrene, Benzo[a]pyrene, Indeno(1,2,3-cd)pyrene,
Dibenzo[a,h]anthracene, Benzo[g,h,i]perylene.
Inorganic Acids:
Hydrochloric, Phosphoric, Sulfuric, Nitric, Hydrofluoric.
Metals:
Platinum, Titanium, Molybdenum, Zirconium, Silver, Aluminum, Beryllium, Cadmium,
Calcium, Chromium, Cobalt, Copper, Iron, Magnesium, Manganese, Sodium, Nickel, Lead,
Tin, Vanadium, Zinc.
Volatile organics:
1,1,1-Trichloroethane, Cyclohexane, Carbon Tetrachloride, Benzene, Cyclohexene,
n-Heptane (n-C7), 1,2-Dichlorpropane, Trichloroethane, 1,4-Dioxane, Methylcyclohexane,
Methylisobutylketone, Toluene, n-Octane (n-C8), Tetrachloroethane, Chlorobenzene,
Ethylbenzene, para-Xylene, Bromoform, Styrene, o-Xylene, n-Nonene, n-Nonane (n-C9),
1,1,2,2-Tetrachloroethane, Cumene, Mesitylene, Alpha-methylstyrene, 1,3-Dichlorobenzene,
1,4-Dichlorobenzene, 1,2-Dichlorobenzene, Benzyl Chloride, alpha-Terpine, D-Limonene,
4-tert-Butyltoluene, 1,2,4-Trichlorobenzene, Naphthalene, 4-Phenylcyclohexene, n-Decane
(n-C10), n-Decene, n-Undecene, n-Undecane (n-C11), n-Nonanal, n-Dodecane (n-C12),
n-Tridecane (n-C13), n-Tetradecane (n-C14), n-Pentane (n-C15), n-Hexadecane (n-C16).
Others:
Formaldehyde and Sulfur Dioxide.
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A-3
EXHIBT 1: Air Sampling Results
U.S. EMBASSY, KUWAIT
Results for 3/16
PAHs:
none detected
detection limit: 2 - 4.6 ppb
Sulfur Dioxide:
none detected
detection limit: 0.04 mg/m3
Inorganic Acids:
none detected
detection limit: 1 - - 6 ppb
VOCs:
Benzene 0.4 ppb, n-Heptane 0.13 ppb, Toluene 0.61 ppb, Ethylbenzene 0.1 ppb,
para-Xylene 0.29 ppb, o-Xylene 0.12 ppb.
Metals:
Na < 1.0 ug/m3, Mg 2 ug/m3, Fe 2 ug/m3, Ca 8 ug/m3, AI 2 ug/m3.
Results for 3/17
PAHs:
Naphthalene 0.31 ppb
Sulfur Dioxide:
< 0.02 mg/m3
Inorganic Acids:
HCI 3.0 ppb, H2SO4 1.0 ppb, HNO3 2.0 ppb
VOCs:
Cyclohexane 1.31 ppb, Benzene 4.0 ppb, n-Heptane 6.0 ppb, TCE 0.7 ppb,
Methylcyclohexane 2.0 ppb, Toluene 7.7 ppb, n-Octane 3.0 ppb, Ethylbenzene 1.7 ppb,
p-Xylene 5.4 ppb, Styrene 0.4 ppb, o-Xylene 2.4 ppb, n-Nonane 1.9 ppb, Cumene 0.2 ppb,
Mesitylene 0.6 ppb, D-Limonene 0.1 ppb, n-Decane 1.5 ppb, n-Undecane 1.0 ppb, n-C12
0.7 ppb, n-C13 0.4 ppb.
Metals:
Na 10 ug/m3, Mg 2 ug/m3, Fe 3 ug/m3, Ca 10 ug/m3, AI 2 ug/m3.
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A-4
EXHIBT 1: Air Sampling Results
U.S. EMBASSY, KUWAIT, continued
Results for 3/18
PAHs:
Naphthalene 0.16 ppb
Sulfur Dioxide:
< 0.05 mg/m3
Inorganic Acids:
HCI 6 ppb, HNO3 2 ppb, H2SO4 1.0 ppb.
VOCs:
Cyclohexane 1.2 ppb, Benzene 5.2 ppb, n-C7 8.1 ppb, Methylcyclohexane 3.0 ppb, Toluene
14.6 ppb, n-C8 4.7 ppb, Ethylbenzene 3.2 ppb, p-Xylene 9.3 ppb, o-Xylene 4.7 ppb, n-C9
2.7 ppb, Cumene 0.3 ppb, Mesitylene 1.3 ppb, Naphthalene 0.18 ppb, n-C10 1.7 ppb, n-C11
1.0 ppb, n-C12 0.7 ppb, n-C13 0.3 ppb.
Metals:
Na 5 ug/m3, Mg 1 ug/m3, Fe 1 ug/m3, Ca 7 ug/m3, AI 1 ug/m3.
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A-5
EXHIBT 1: Air Sampling Results
CAMP FREEDOM
Results For 3/17
PAHs:
Naphthalene 0.09 ppb, 2-Methyinaphthalene 0.06 ppb, 1-Methylnaphthalene 0.04 ppb.
Sulfur Dioxide:
0.12 mg/m3 0.045 ppm
Inorganic Acids:
HCI 16 ppb, HF 23 ppb, H2SO4 31 ppb
VOCs:
Cyclohexane 7 ppb, Benzene 4.6 ppb, n-C7 25.6 ppb, Methylcyclohexane 9.5 ppb, Toluene
13 ppb, n-C8 18 ppb, Ethylbenzene 2.7 ppb, p-Xylene 8 ppb, o-Xylene 4.5 ppb, n-C9 10.9
ppb, Cumene 0.5 ppb, Mesitylene 1 ppb, Naphthalene 0.18 ppb, n-C10 6.3 ppb, n-C11 4.1
ppb, n-C12 2.3 ppb, n-C13 0.9 ppb, n-C14 0.5 ppb. These levels may also include
emissions from vehicles in the area.
Metals:
No Data.
Results for 3/18
PAHs:
Naphthalene 0.28 ppb
Sulfur Dioxide:
<0.04 mg/m3, < 0.015 ppm
Inorganic Acids:
HNO3 4.0 ppb, H2SO4 4 ppb.
VOCs:
Cyclohexane 2.8 ppb, Benzene 6.9 ppb, n-C7 9.7 ppb, Methylcyclohexane 3.9 ppb, Toluene
16 ppb, n-C8 5.4 ppb, Ethylbenzene 3.1 ppb, p-Xylene 9.5 ppb, Styrene 0.3 ppb, o-Xylene
4.5 ppb, n-C9 3 ppb, Cumene 0.3 ppb, Mesitylene 1.1 ppb, n-C10 1.5 ppb, n-C11 0.8 ppb,
n-C14 0.2 ppb.
Metals:
AI 2 ug/m3, Ca 8 ug/m3, Fe 2 ug/m3, Mg 2 ug/m3, Na 3 ug/m3.
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A-6
EXHIBT 1: Air Sampling Results
MEPA DHAHRAN, SAUDI ARABIA
Results For 3/13
PAHs:
none detected
Sulfur Dioxide:
<0.1 mg/m3, <0.037 ppm
Inorganic Acids:
H2SO4 5 ppb.
VOCs:
Benzene 0.3 ppb, Cyclohexane 0.1 ppb, Toluene 0.5 ppb, Ethylbenzene 0.1 ppb, p-Xylene
0.2 ppb, o-Xylene 0.1 ppb, Mesitylene 0.04 ppb.
Metals:
AI 2 ug/m3, Ca 5 ug/m3, Fe 2 ug/m3, Mg 2 ug/m3, Na 1 ug/m3.
Results For 3/14
PAHs:
none detected
Sulfur Dioxide:
<0.08 mg/m3, < 30 ppb.
Inorganic Acids:
HNO3 2 ppb, H2SO4 6 ppb.
VOCs:
Cyclohexane 0.2 ppb, Benzene 0.5 ppb, n-C7 0.8 ppb, Methylcyclohexane 0.3 ppb, Toluene
0.7 ppb, n-C8 0.4 ppb, Ethylbenzene 0.1 ppb, p-Xylene 0.3 ppb, o-Xylene 0.1 ppb, n-C9
0.3 ppb.
Metals:
AI 3 ug/m3, Ca 14 ug/m3, Fe 3 ug/m3, Mg 4 ug/m3, na 8 ug/m3.
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A-7
EXHIBT 1: Air Sampling Results
U.S. EMBASSY RIYADH, SAUDI ARABIA
Results For 3/28
PAHs:
none detected
Sulfur Dioxide:
< 0.08 mg/m3, < 30 ppb
Inorganic Acids:
NO3 3 ppb, H2SO4 < 2 ppb.
VOCs:
Benzene 0.3 ppb, Toluene 0.6 ppb, Ethylbenzene 1.0 ppb, p-Xylene 0.3 ppb.
Metals:
AI 2 ug/m3, Ca 4 ug/m3, Fe 1 ug/m3.
PORT SHUAYBAH
Results For 3/17
PAHs:
no data
Sulfur Dioxide:
< 0.05 mg/m3, , 19 ppb
Inorganic Acids:
H2SO4 19 ppb.
VOCs:
Benzene 4.2 ppb, n-C7 13 ppb, Methylcyclohexane 5.3 ppb, Toluene 15 ppb, n-C8 5.6 ppb,
p-Xylene 6.9 ppb, Ethylbenzene 2.2 ppb, o-Xylene 2.9 ppb, n-C9 3.8 ppb, Cumene 0.2
ppb, n-C10 2.9 ppb, n-C11 1.9 ppb, n-C12 1.4 ppb, n-C13 0.8 ppb.
Metals:
Ca 4 ug/m3, Na 7 ug/m3.
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A-8
EXHIBT 1: Air Sampling Results
AI MAQUA OIL FIELD
Results for 3/15
PAHs:
no data
Sulfur Dioxide:
<0.3 mg/m3, <0.1 ppm
Inorganic Acids:
no data
VOCs:
Cyclohexane 0.6 ppb, Benzene 1.8 ppb, n-C7 3.2 ppb, Methylcyclohexane 1.1 ppb, Toluene
2 ppb, Ethylbenzene 0.4 ppb, p-Xylene 1.4 ppb, o-Xylene 0.8 ppb, n-C9 2.8 ppb,
Mestilylene 0.3 ppb, n-C10 3.3 ppb, n-C11 3.5 ppb, n-C12 3.3 ppb, n-C13 1.8 ppb, n-C16
1.1 ppb.
Metals:
AI 6 ug/m3, Ca 6 ug/m3, Fe 6 ug/m3.
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A-9
EXHIBT 1: Air Sampling Results
AI AHMADI OIL FIELD
Results For 3/16
PAHs:
none detected
Sulfur Dioxide:
0.45 mg/m3, 0.17 ppm
Inorganic Acids:
H2SO4 27 ppb, HNO3 10 ppb, HCI 9 ppb.
VOCs:
Cyclohexane 0.4 ppb, Benzene 3.9 ppb, n-C7 2.5 ppb, Methylcyclohexane 1 ppb, Toluene
2 ppb, n-C8 2.3 ppb, Ethylbenzene 0.5 ppb, p-Xylene 1.5 ppb, o-Xylene 0.9 ppb, n-C9 2.9
ppb, Mesitylene 0.4 ppb, Naphthalene 0.5 ppb, n-C10 3.4 ppb, n-C11 3.8 ppb, n-C12 4 ppb,
n-C13 2.9 ppb, n-C14 2.9 ppb, n-C15 2 ppb, n-C16 1.7 ppb.
Metals:
AI 8 ug/m3, Ca 50 ug/m3, Fe 20 ug/m3.
Formaldehyde:
8 ppb. Hydrogen Sulfide: analysis not completed
SUMMA Data:
SO2 20 ppm; CO 1.9 ppm
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A-10
EXHIBT 1: Air Sampling Results
AI BURGAN OIL FIELD
Results For 3/17
PAHs:
none detected; detection limit 50 ppb
Sulfur Dioxide:
1.8 mg/m3, 0.8 ppm
Inorganic Acids:
H2SO4 30 ppb, HNO3 32 ppb, HCI 15 ppb.
VOCs:
Benzene 8.7 ppb, n-C7 4.6 ppb, Methylcyclohexane 2.5 ppb, Toluene 4.31 ppb, n-C8 5.1
ppb, Ethylbenzene 1.3 ppb, p-Xylene 4.2 ppb, o-Xylene 2.4 ppb, n-C9 7.1 ppb,
Naphthalene 1.6 ppb, n-C10 9.1 ppb, n-C11 10.4 ppb, n-C12 11.3 ppb, n-C13 7.8 ppb,
n-C14 7.4 ppb, n-C15 5.4 ppb, n-C16 4.6 ppb.
Metals:
AI 20 ug/m3, Ca 120 ug/m3, Fe 20 ug/m3, Mg 30 ug/m3.
Formaldehyde:
20 ppb;
SUMMA Data:
SO2 0.23 ppm, CO 1.6 ppm, H2S none detected (0.1 ppm detection limit.)
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A-11
EXHIBT 1: Air Sampling Results
AI WAFRA OIL FIELD
Results for 3/19
PAHs:
no data
Sulfur Dioxide:
none detected 0.3 mg/m3, 0.11 ppm.
Inorganic Acids:
none detected 10 ppb detection limit
VOCs:
Benzene 2.3 ppb, n-C7 0.6 ppb, Methylcyclohexane 1.6 ppb, Ethylbenzene 0.3 ppb,
o-Xylene 0.4 ppb, Mesitylene 0.4 ppb
Metals:
no data
Hydrogen Sulfide:
awaiting results.
SABIRIYAH OIL FIELD
Results For 3/17
SUMMA DATA:
Ground Level Sample:
H2S none detected (0.1 ppm); SO2 13 ppm; CO 1.1 ppm; NO and NO2 none detected
VOCs:
Benzene 9.8 ppb, Toluene 8.7 ppb, Ethylbenzene 10 ppb, m&p-Xylene 27.8 ppb o-Xylene
24 ppb, m-Ethyltoluene 15.8 ppb, n-C6 83 ppb, n-C7 60 ppb, n-C8 91 ppb, n-C9 91 ppb,
n-C10 89 ppb, n-C11 65 ppb.
3000 ft Sample:
H2S none detected; SO2 0.08 ppm, CO none detected; NO and NO2 none detected 0.5
ppm.
1000 ft Sample:
H2S, SO2, CO, NO, and NO2 none detected.
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A-12
Table 1
Kuwait Oil Well Fires Real Time Monitoring
March 13-20, 1991
Site, Date, Time
Total
Sulfur
Hydrogen
Volatile
Particulate
Dioxide
Sulfide
Organics
mg/m³
ppm
ppm
ppm
1) MEPA Faciltiy, Dhahran, SA
.170
0.0
0.0
0.0
3/13 1100 hrs
MEPA Facility
.048
0.0
0.0
0.0
3/14 1300 hrs
2) AI Dhuba
.420
0.0
0.0
0.0
3/15 1430 hrs
3) Umn AI Haiman
.320
0.0
0.0
0.0
3/15 1500 hrs
4) Mina Abdulla
.250
0.0
0.01
0.6
3/15 1530 hrs
5) Near AI Maqwa Oil Field 3/15
.010
0.0
0.024
0.8
1630 hrs
6) In AI Maqwa Well Plume
5.4
0.0
0.006
0.8
3/15 1700 hrs
7) U.S. Embassy
.01
0.0
0.001
0.0
3/06 0900 hrs
U.S. Embassy
.055
1.0
0.005
0.2
3/18 1230 hrs
8) In AI Ahmadi Well Plume
---
0.0
0.032
0.0
3/16 1230 hrs
In AI Ahmadi Oil Field
.120
1.0
0.009
0.0
3/16 1300 hrs
9) In AI Burgan Well Plume
1.0
0.015
0.0
-
3/17 1100 hrs
10) In Sabiriyan Well Plume,
---
1.0
0.042
2.5
Pooled Oil
3/18 1530 hrs
11) In AI Wafra Well Plume
.050
2.0
0.015
0.0
3/19 1200 hrs
12) Freedom City
---
---
---
---
13) U.S. Embassy Riyadh, SA
.032
0.0
0.0
0.0
3/20 1300 hrs
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A-13
Table 2
Kuwait Oil Well Fires Real Time Monitoring
March 24-27, 1991
Site, Date, Time
Total
Sulfur
Hydrogen
Volatile
Particulate
Dioxide
Sulfide
Organics
mg/m³
ppm
ppm
ppm
1) AI Safer Motorway and
.825
2.0
0.0
0.3
Wafra Road
(15 min.
3/24 1440 hrs
avg.)
2) AI Ahmadi Gathering
.359
0.0
0.0
0.0
Center #22
(15 min.
3/24 1530 hrs
avg.)
3) AI Ahmadi Hospital
.222
0.0
0.0
0.0
3/24 1530 hrs
(32 min.
avg.)
4) 1 mi. NW of Station
.256
0.0
0.0
0.0
2 in Ahmadi Oil Field
(10 min.
3/24 1730 hrs
avg.)
5) AI Maga Oil Field,
.034
1.0
0.0
0.6
.5 mi south of 7th
(17 min.
Ring Road near oil pool
avg.)
3/25 1400 hrs
6) AI Ahmadi Oil field
.561
0.0
0.003
0.6
(same as Station 4)
(13 min.
3/25 1500 hrs
avg.)
7) AI Ahmadi Hospital
.295
0.0
0.0
0.0
(same as Station 3)
(15 min.
3/25 1545 hrs
avg.
8) AI Safer and Wafra
.065
0.0
0.002
0.0
Road
(16 min.
3/25 1615 hrs
avg.)
9) AI Ahmadi Hospital
.935
0.0
0.0
0.2
(same as Station 3 and 7)
(20 min.
3/27 1020 hrs
avg.)
10) AI Ahmadi Hospital
.457
---
---
---
(same as Stations 3, 7,
(20 min.
and 9)
avg.)
3/27 1040 hrs
11) AI Ahmadi Hospital
.457
---
---
---
(same as Stations 3, 7, 9,
(20 min.
and 10)
avg.)
3/27 1100 hrs
12) Shuaiba Port
.468
0.0
0.0
0.0
3/27 1215 hrs
(15 min.
avg.)
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A-14
Site, Date, Time
Total
Sulfur
Hydrogen
Volatile
Particulate
Dioxide
Sulfide
Organics
mg/m³
ppm
ppm
ppm
13) AI Safer Motorway and
.119
0.0
0.0
0.0
Wafra Road
(12 min.
3/27 1300 hrs
avg.)
14) 16 Kilo-meters SE of AI
.257
0.0
0.0
0.0
Safer and Wafra Roads
(12 min.
3/27 1330 hrs
avg.)
15) 27 Kilo-meters SE of AI
.227
---
---
---
Safer and Wafra Roads
(15 min.
3/27 1350 hrs
avg.)
16) 5 Kilometers South of
.072
---
---
---
Khafji, Saudi Arabia
(14 min.
3/27 1510 hrs
avg.)
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A-15
Table 3
Sulfur Dioxide Bubbler Measurements
(Acidimetric Method)
Temporary Hospital Locations in Kuwait City
March 13-24
Hospital
Date
Concentration (ug/m³)
Adan
3/14/91
40.31
3/17/91
43.88
3/18/91
39.34
3/19/91
26.18
3/20/91
27.68
3/23/91
28.16
3/24/91
15.99
Mubarek AI Kabeer
3/13/91
193.66
3/18/91
56.48
3/19/91
58.11
3/20/91
42.34
3/23/91
43.43
3/24/91
23.72
AI Farwaniya
3/13/91
81.32
3/16/91
19.21
3/17/91
29.56
3/18/91
134.81
3/19/91
218.65
3/20/91
27.57
3/23/91
26.66
3/24/91
10.54
AI Jahra
3/16/91
32.03
3/18/91
66.59
3/19/91
32.54
3/23/91
13.92
3/24/91
9.90
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A-16
U.S. Air Assessment Team
Real-Time Sampling Locations, March 24-27
IRAQ
30°N
Shatt al-Arab
IRAN
KUWAIT
I AI Safer & Wafra Roads
(3 measurements taken)
2 AI Ahmadi
Gathering Center #22
3
Hospital (5 measurements taken)
Mina
24
Ahmadi
Oil Field (2 measurements taken)
29°
3 AI Maqwa Oil Field
I
4 Shuaiba Port
Ras Al-Quilayah
5 16 Km SE of AI Safer & Wafra Roads
5
6
Ras Al-Zawr
6 27 Km SE of AI Safer & Wafra Roads
7 5 Km S of Khafji, Saudi Arabia
Khafji
SAUDI
7
50 km
28°
Saffaniya
ARABIA
Karan I.
H
48°
49°
50°
51°E
APPENDIX B
PROPOSED HEALTH PLAN
I.
HEALTH IMPACT OF THE KUWAIT OIL WELL FIRES
A.
Activities and Results
The activities of the health component have been divided into two regions: Kuwait and Saudi
Arabia. There are two goals behind these activities:
1.
To determine through interviews with responsible health professionals whether there are or
have been any health occurrences that might be associated with the oil smoke plume.
2.
To ascertain the health care and toxicology assets of each region that could be applied to
health surveillance, epidemiology, and clinical field trials.
To address these objectives, medical records were reviewed (when available) and meetings were
held with public health officials, DOD health representatives, and US embassy staff. Where possible, results
from health data collection were correlated with preliminary real-time air monitoring data.
Saudi Arabia
Activities in Saudi Arabia have included meetings with:
CDC Field Epidemiology Training Program (FETP);
Ministry of Health;
Deputy Chief of Mission, US Embassy, Riyadh;
US Consul General to Dhahran;
Meteorological and Environmental Protection Agency (MEPA);
Saudi Arabian Oil Company (Saudi ARAMCO);
King Fahd University for Petroleum and Mining, Research Institute (KFUPM);
Physicians of the MC USN;
General Director of Infectious and Parasitic Diseases, Saudi Ministry of Health;
Director of Qataif Regional Primary Care Centers;
Sixty physicians from Eastern Province.
Kuwait
Activities in Kuwait have included meetings with:
Minister of Public Health;
Head of Environmental Health Laboratory;
Head of Allergy Center;
Pulmonary and Casualty Ward physicians at Mubarak Hospital;
Review of outpatient records for March 2 and March 12 at Mubarak Hospital;
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B-1
Ambassador Gnehm and staff;
Embassy Medical Services Officer;
Congressional delegation;
The Director and staff of the Kuwait Allergy Center
Epidemiologist in the Ministry of Health;
Department of Preventive Medicine;
Assistant Undersecretary for Public Health in the Ministry of Public Health;
Scientists from the University of Kuwait;
Director and Assistant Director of the Kuwait
Institute for Scientific Research;
The Secretary General of the Kuwait Institute for
Medical Specialization;
Head of Preventive Medicine, Al-Ahmadi Hospital
US and UK Military physicians;
Ambassador Gnehm and staff.
Regional - WHO
Meeting with WHO representative in Kuwait.
Military
Review of infirmary records of troops stationed in Kuwait City;
Interviews with Kuwaiti soldiers stationed in the oil fields;
Meeting with US Central Command (CENTCOM) medical personnel in Riyadh.
Oil Workers
Not addressed to date.
B.
Specific issues addressed in these meetings include:
1.
Knowledge (preferably first hand) of any apparent increases in respiratory complaints
resulting from the oil smoke plume.
2.
Direct examination (where possible) of recent medical charts that could help in ascertaining
the presence of any ongoing respiratory problems associated with the oil smoke plume.
3.
The accessibility of health care records (current or past) that could be utilized in health
surveillance and epidemiology.
4.
The existence of facilities, such as pulmonary function labs, that could be used in any
clinical field studies involving specific health endpoints.
5.
Prevalence of asthma in the Gulf area and its putative etiology, as well as the incidence of
asthma-like symptoms in the population.
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B-2
6.
Prevalence of disease (such as fibrosis) related to the high background sand particulate
concentrations.
7.
The role of different governmental and academic institutions in executing health monitoring
and epidemiology.
8.
Multiple routes of exposure to toxicants, i.e. inhalation of smoke, dermal absorption of
surface deposited smoke and oil, and ingestion of oil and oil byproducts through
contamination of groundwater and Gulf water.
9.
Public response within Kuwait to the current situation.
10.
The existence of efforts that have been initiated in the areas of health surveillance and
epidemiology.
II.
FINDINGS
1.
Based on initial preliminary results of real-time air monitoring for hydrogen sulfide (H2S) and
sulfur dioxide (SO2) (see monitoring results), and the current and likely meteorological
conditions in Kuwait and the Gulf region, an acute health hazard does not now appear likely
to be posed by the H2S and SO2 fires for the general population. Assuming that the
ground-based data obtained by the monitoring group in Kuwait is representative of
exposures and meteorological trends for this region, it is highly unlikely that any short-term
increases in mortality will occur in Kuwait City due to air pollution. Two factors mitigate
against the occurrence of any situation similar to that in London in the 1950's or the
Mousse Valley in the 1930's: 1) the absence of weather conditions that lead to significant
inversions or fogs, and 2) the flat topography which prevents pollutant buildups such as
those that often occur in valleys and areas surrounded by mountains. However, under less
benign meteorological conditions than those that currently exist (e.g., in the case of poor
air mixing at ground level or in the event of plume touchdown) shorter-term upward
excursions of air pollutants may pose increased risk of acute health effects. Because of the
extreme toxicity associated with H2S exposure, oil field workers should take appropriate
precautions at all times.
2.
High risk populations such as asthmatics and individuals with underlying respiratory
conditions appear to be at greatest risk of developing adverse effects from the current
pollution situation. Since the fires began in late February, physicians have noted that
asthmatics have experienced more episodes of wheezing, and episodes that are less
responsive to usual medication regimens. Observations based on limited reports raises
concerns about the potential effects on other sensitive populations such as children, the
elderly, individuals with cardiac disease, and others.
3.
A health survey of Marines is currently underway. It is being conducted by Capt. Stephen
Wignal and Cmdr. Mary Anderson of the USN stationed in Jubayal, Saudi Arabia. Three
battalions (cohorts) of 900 Marine each is participating in the survey. The first cohort
entered Kuwait at the start of ground fighting and is currently in Kuwait. The second cohort
entered Kuwait at the start of ground fighting and was redeployed to Jubayal at the
cessation of ground fighting. The third cohort has never entered Kuwait and is stationed
at a distance from the oil smoke. The survey questionnaire was reviewed by Drs. Gerrity
and Seligman. Suggestions and modifications were made. The beginning of this survey
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was observed by Dr. Seligman in Jubail. Results should be available within a matter of
weeks. Dr. Stephen Wignal will be in the U.S. on April 3 and might, if desired, be available
for a meeting to discuss this survey. Sean Drysdale, a preventive medicine physician
responsible for the 1st Armored Division of the U.K. is attempting to undertake surveillance
of his troops and may connect with the USN effort in Jubayal.
4.
In discussions with Drs. Salek Al-Kandar and Ali Al-Saif of the Kuwait Ministry of Public
Health it became apparent that Kuwait had spent the past 30 years building its
communicable disease epidemiology program with the goal of reducing communicable
diseases. Having achieved this goal prior to August 2, 1990, there were initial efforts at
expanding into non-communicable diseases including environmentally related diseases.
Since August 2, 1990 this initial effort was completely set back. There are few if any
professionals within Kuwait who have training in environmental epidemiology. Despite this,
some initial efforts are underway. Dr. Diaa Al-Din'Mohamed, the Director of the Kuwait
Allergy Center, has begun the effort to collect incidence reports of asthma from Kuwait
health care facilities and attempt to compare this data with historical data. Considering the
shortage of manpower at the Center (one technician and two physicians compared with a
pre-war staff of 14 physicians and about the same number of technicians) this is likely to
be an arduous process. The Allergy Center has 4 Jaeger Pulmoscreen spirometry systems
and a Morgan body box that could be used for a pulmonary function epidemiology study.
Other types of laboratory equipment for doing biochemistry or analytic chemistry are very
limited. Dr. Walid Doud, the Director of Preventive Medicine at Kuwait's Al-Ahmadi Hospital,
has begun a longitudinal study of approximately 100 people in the surrounding community.
This population will include asthmatics and patients with COPD as well as healthy subjects.
Pulmonary function (spirometry and peak flow measurements) will be made. There are two
Vitalographs at the hospital for this purpose. The number of subjects participating in this
study is limited by the pulmonary function and personnel resources at the hospital.
Additionally, they have some limited air monitoring capability at the hospital.
a. Outside of a few laboratories, such as the air monitoring stations within the purview of
the Kuwait Environmental Health Monitoring Laboratory, the Kuwait Ministry of Public
Health, the scientific infrastructure of Kuwait has been virtually dismantled. Major pieces
of analytical equipment in chemistry laboratories, biochemistry laboratories, pathology
laboratories, etc. have been stolen or destroyed. These laboratories include those at the
Kuwait Institute for Scientific Research and the University of Kuwait. The Chest Hospital,
however, still is in possession of its pulmonary function testing equipment.
b. In a meeting with Dr. Al-Jefri (General Director of Infectious and Parasitic Diseases, Saudi
Ministry of Health) he indicated a strong desire to involve the CDC Field Epidemiology
Training Program in establishing a surveillance effort in the Eastern province for asthma.
He would like a plan of action regarding both surveillance efforts, and epidemiologic and
clinical studies to be reviewed by himself and the General Director for Environmental Health.
In a meeting with Dr. Khazi Al-Qatari (Director of Qataif Regional Primary Care Centers) it
was learned that there is currently in place a surveillance system for HTN, diabetes, sickle
cell/G6PD, and asthma (and communicable diseases). The physicians are very eager to
get involved in clinical studies and in utilizing their current surveillance efforts for tracking
potential health effects. They were very eager to receive the air monitoring results to guide
them in making decisions on health studies. Dr. Al-Qatari and others would like to meet
with either myself or the returning health team to discuss further plans. He is also
concerned about the air pollution on the 20% of the population that have sickle cell,
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thalassemia, and other hemoglobinopathies. He also stressed the need to get support from
the Ministry of Health and from the Regional Headquarters in Damman.
5.
The Kuwait Ministry of Public Health has articulated enthusiastic willingness to participate
in a program (such as the CDC Field Epidemiology Training Program) that would
simultaneously train physicians in epidemiology (with emphasis on environmental
epidemiology) and conduct field epidemiology studies.
6.
In addition to having the highest particulate concentrations in the world, the Gulf area also
has the highest prevalence of asthma and other allergic respiratory disorders. It is presently
felt that such a high prevalence is due to a combination of pollen and sand. The pollen of
the prosopis tree (related to the mesquite tree) appears to be a particular problem. This
tree is not indigenous to the area but was imported from Iran. Furthermore, there appears
to be no evidence that the high sand particulate concentrations lead to an increase in lung
fibrosis in the population.
7.
Concern among the scientific community, as expressed by some of its leaders, has arisen
over health risks from routes of exposure other than inhalation. Risk from the ingestion of
oil products that have seeped into the ground water appears to be particularly high.
Additionally the deposition of oily deposits on surface water supplies (including the Gulf)
has given rise to concern. One scenario that had been proposed, but may or may not be
a problem, is the interaction of oil contaminated Gulf water with the chlorination process
at the desalination plants. It is feared that since the chlorination is done at high
temperatures, various halogenated hydrocarbons that may be carcinogenic, could be
formed and subsequently ingested.
8.
There were expressions of concern for the apparent growing fear within the public of the
effects of the oil well fires. There is a desire for factual information that can be
disseminated to the public coupled to information about precautions that could be taken
to minimize exposure and risk.
9.
Parties such as the Ministry of Public Health, KISR, and Kuwait University, have said funding
for surveillance, epidemiology, and research is not a problem (i.e. Kuwait is willing to foot
the bill). However, it was also said that there are political problems in convincing the ruling
authorities that these issues should receive high priority in spending. It was thought that
a determination by an international scientific body such as WHO, that studies of the health
impacts of the oil smoke problem should receive high priority, would provide the necessary
impetus. Discussions with Ambassador Gnehm confirm this observation. An umbrella MOU
has been signed between the US and Kuwait that would facilitate funding by Kuwait of US
research efforts. Subsequent (more simple) MOU's would have to negotiated by individual
USG agencies. Given the support of the ruling authorities, financial support of Kuwait for
health impact studies could be obtained.
10.
The observation in the first Interim Report that biological samples from cadavers cannot be
obtained apparently applies only to Saudi Arabia. Post mortems are legally done in Kuwait.
However it was determined that in most cases it is difficult to convince families to agree.
The exception is when a death occurs in hospital due to unknown causes. Then a post-
mortem is legally required.
11.
Many of the parties that would be involved in surveillance and epidemiology have been
identified in both Saudi Arabia and Kuwait. Many of the problems and confounders that
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would impact on study designs have been identified. A clearly defined strategy of approach
to the health impact problems on a large scale has yet to be developed.
12.
On March 24, 1991 the US Air Team in Kuwait experience what was described by people
in Kuwait as the worst conditions seen thus far. One qualitative observation worth noting,
that is better elucidated by the monitoring team, is that the conditions appeared to be of
the nature of an inversion. The relative humidity was high and the air was very still away
from the oil fields. Within the oil fields there was a significant breeze probably due the
inflow of air feeding the individual fires.
IV.
PROBLEMS/ISSUES
Depopulation of Kuwait has left hospitals and clinics short-staffed. Other priorities currently
dominate consideration such as electricity, water, adequate medicine, restoration of basic equipment, getting
the telephones working. Support and clerical staff in the hospitals and clinics have left the country,
remaining staff feel overworked.
Large shifts in population over the next months with the repopulation of Kuwait will make it difficult
to accurately determine denominators for disease rates. Similarly, recommendations encouraging asthmatics
and other high risk individuals to stay out of Kuwait is likely to make an accurate assessment of the
magnitude of the health problem difficult.
The presence of high backgrounds of particles in Kuwait and Saudi Arabia pose two problems: 1.)
the separation of effects of the oil smoke plume from those of the sand; and 2) the role, if any, that sand
may play in increasing susceptibility to the health effects of the oil smoke plume.
Given the unprecedented nature of the current circumstances and that the exposures under
consideration may only last two years, it is difficult using current scientific knowledge to project with
certainty chronic effects. Past epidemiological studies have focussed primarily on longer term exposures.
Cancer risks can be prorated for shorter exposure times based on current EPA methodologies. There is
some evidence that non-cancer pulmonary effects such as loss of lung function, and development of
asthma, can occur as a result of short-term exposures especially if affected individuals have pre-existing lung
disease or might be compromised by poor nutrition.
Ozone and acid aerosols should receive special attention since they may not be formed in the
immediate vicinity of the oil smoke plume, but be later formed and transported many miles downwind. In
the US high ozone concentrations generally occur 20-40 miles downwind of major population centers. There
is scientific evidence for synergism between ozone and other pollutants with respect to health effects.
The role of current pharmacotherapy in the treatment of asthma could significantly reduce any
possible morbidity and mortality that might otherwise result from a serious high concentration episode in
the unlikely event such were to occur.
The use of biological samples from cadavers is prohibited and should not realistically be considered
as an option for further study.
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V.
RECOMMENDATIONS
Medical surveillance, epidemiological studies, and clinical field studies examining specific health
endpoints (see appendix) should be conducted primarily in Kuwait and in extreme Northeastern Saudi
Arabia, and secondarily in regions of the Eastern Province further south to Dhahran, to quantitatively
ascertain whether there are significant increases in morbidity and mortality, short-term and long-term, as a
result of the oil smoke plume. Prospective or concurrent studies can be conducted examining more specific
clinical and toxicological issues. Of utmost importance in any of these investigations is the need to link
determinations of health effects, regardless of endpoint, with exposure monitoring data. The monitoring
strategy being developed in parallel with this section addresses this requirement.
From the health perspective the following sequence of actions are being recommended. The
sequence of these actions represents an approach to addressing health issues related to the oil smoke
plume. Some of the early actions have already been taken.
1.
Link air monitoring system to public health response, particularly for high risk populations, including
specific advice regarding courses of action to prevent health effects in high risk populations.
2.
Collaborate with Kuwaiti and Saudi health authorities in the performance of surveillance to:
a.
assess the effectiveness of an early warning system to limit or reduce air pollution-related
morbidity,
b.
to monitor trends in respiratory disease rates for the period of the oil fires and beyond.
3.
Develop close collaboration between Kuwaiti, Saudi, WHO and DOD health officials and scientists
from the CDC and EPA in the design and conduct of short- and long-term epidemiological and
clinical studies of the health effects of the oil fires.
4.
Collect plume samples for in-vitro and in-vivo toxicity testing and dose response assessment.
5.
Assess more accurately the acute and chronic risk based on exposure data and in-vitro and in-vivo
toxicity data.
6.
Require completion of permanent service records for all active and reserve personnel that served
in the KTO. Such records would be vital in the event that future questions are raised concerning
the health impact of military service in Kuwait.
7.
Initiate preventative measures for military personnel such as, but not limited to, the use of dust
masks and limiting exercise on bad days. The potential health effects of the smoke should be a
factor in considering redeployment and/or rotation of troops in the region.
8.
Medical facilities in the affected areas should be aware of the potential for increased frequency of
asthma attacks and should insure that adequate supplies of appropriate medications are on hand.
9.
Revise and issue a health advisory for US personnel and governments in the region.
10.
Give strong consideration to USPHS involvement directly or as part of a multinational WHO effort
in rebuilding the public health infrastructure in Kuwait a) upon request of the Kuwaiti government,
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and b) after stabilization of the political environment and restoration of vital services such as
electricity, water, and telephones.
11.
A meeting of relevant parties from the EPA, CDC, and NIEHS should be convened in Washington
at the earliest time to discuss planning for studies of the health impacts of the oil well fires. Experts
outside of the USG should also be present to provide input.
12.
An expert(s) in groundwater, soil, and food contamination by oil should be brought into a future
team to assess the impacts of the oil pooling and combustion product deposition on population
exposure. The goal should be to ascertain whether or not there is a problem in these areas.
13.
The establishment of a central coordinating "Ministry" dealing with the oil fire problem might be
suggested to the government of Kuwait. This might facilitate overall coordination between all parties
concerned.
14.
Daily satellite photographs of the position of the smoke plume beginning with its inception should
be obtained from NOAA. This would facilitate establishing roughly the exposure pattern over time.
15.
Demographic information is needed for the country of Kuwait. Information prior to August
2, 1990 would help establish the major population centers. Current information will be
difficult to obtain but should be sought after.
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APPENDIX C
A REGIONAL GULF AIR MONITORING PLAN
IN RESPONSE TO THE
1991 KUWAITI OIL FIELD FIRES
I.
INTRODUCTION
Purpose of the Plan
Team Membership
Concerns and Questions - Short and Longer Term
Basic Understandings
II.
BACKGROUND
Nature of the Fires and Oil Field Locations
Qualitative Meteorological Observations
Preliminary Air Quality Information
Health Issues and Concerns
Data Bases and Information Management
III.
RECOMMENDATIONS
Preliminary Findings and Conclusions to Date
Phased Steps for Expanding the Network
Measurement Parameters at each Site
Health Monitoring Surveys
IV.
SUMMARY
Preliminary Findings and Conclusions to Date
Basic Network Requirements
Urgency and Timing
Phased Approach to Implementation
Unresolved Issues
ATTACHMENTS
List of existing and proposed air monitoring sites
Locations of existing and proposed air monitoring sites
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APPENDIX C
A REGIONAL GULF AIR MONITORING PLAN
IN RESPONSE TO THE
1991 KUWAITI OIL FIELD FIRES
1.
INTRODUCTION
The U.S. Interagency Air Monitoring Team is working with the Saudi Arabian Meteorology and
Environmental Protection Agency (MEPA) to develop an air monitoring plan for the Gulf region that will
provide information to assess the impact of the [Kuwaiti] fires in Saudi Arabia. This plan is being
discussed and developed with the King Faud University of Petroleum and Minerals in Dhahran, the
Cooperation Council for the Arab States of the Gulf (CCG), and the Saudi Arabian Oil Company
(ARAMCO). The plan is being developed at the request of Dr. Tawfiq, Vice President of the Saudi
Arabian MEPA. Meetings have been held with officials from all of the above mentioned organizations.
1.1 Approach
The Team is gathering information on the existing air monitoring networks in the region operated
by MEPA, ARAMCO, Kuwait, Bahrain, and the Royal Commission of Jubayl and Yunbo. The spatial
distribution of the existing network in the Region is being reviewed as to the location of sites, the air
pollutants and meteorological variables that are monitored at each of these sites and the quality of
existing data. That review is to determine if the existing network needs to be expanded in terms of the
air pollutants and meteorological variables monitored and additional air monitoring stations to determine
the impact from the oil fires. The capabilities of the existing agencies and governments to deal with a
more complete network is also being investigated.
1.2 Objectives of Air Monitoring in the Gulf Region
Air monitoring data is needed for the following reasons:
a.
To provide an Early Warning Health Advisory System for the Gulf Region to respond to the air
pollution resulting from the Kuwaiti oil fires. The proposed Early Warning System could be based on an
adaptation of the U.S. Air Quality Index, the Pollutant Standards Index (PSI), which can be modified to
use Saudi air quality standards. The index would provide for health advisories to the affected
populations so they can minimize their exposure to high pollution levels.
b.
To track the air pollution from the Kuwaiti oil field fires over time to asses the potential long term
health and ecological effects. The air monitoring network proposal being developed is being
coordinated with a parallel effort to develop a health monitoring information system.
C.
To collect samples of airborne particles to perform toxicity testing and dose response
assessment utilizing in-vivo animal models.
d.
To facilitate evaluations of models which are use to predict the local and regional scale behavior
of the oil field emissions. Data from the expanded GULF REGIONAL AIR MONITORING NETWORK of
ambient air quality and meteorological data will be important for those evaluations.
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2.
BACKGROUND
2.1 Preliminary Investigation of the Existing Monitoring Networks
The air quality monitoring sites listed in Table 1 have been identified for each of the Gulf nations
that could contribute monitoring information within the sphere of influence of airborne effluents from the
Kuwait oil fires.
Based upon our review of the existing networks, the principal pollutants which are missing are in
the Saudi network and in the present Kuwaiti network are PM₁₀, which represents particulate matter with
particles less than 10 microns in diameter, polycyclic aromatic hydrocarbons (PAH) and volatile organic
compounds (VOC). With respect to PM₁₀, these are the particles which are most likely to penetrate
deeply into the lung. It should be noted that Kuwait has collected particulate data using an Anderson
Cascade Impactor, with limited size distributions below seven microns within a total suspended
particulate sample. Because of the importance of this particular pollutant and the extensive particulate
resulting from the oil fires, the Team is recommending that special efforts be initiated to gather PM₁₀
data and if possible to determine its constituents - trace metals and hydrocarbons. The
PM₁₀ data collection effort should be supplemented with the collections of PAH samples and if possible,
grab samples for VOC analysis.
An ongoing effort is being conducted to examine the analytical laboratory support for air
monitoring in Kuwait, MEPA, KFUPM, and Saudi ARAMCO. The Kuwaiti laboratory capability to analyze
air and particulate samples has been left largely intact. As of March 27, 1991, two of the three
continuous monitoring stations have been activated and are collecting data. The remaining site has its
continuous sampling equipment however, like the analytical laboratory, is without electrical power.
There is no projected date for power at these locations. The analytical laboratory has had experience
with polyurathane foam (PUF) extractions for PAH measurements (PS-1 sampler) and has done pesticide
extraction and analysis research. The most critical need for the laboratory is obviously power to provide
the basis of future support to the sampling plan. Additionally training must be provided with
documented procedures for these new sampling and analytical procedures, and lastly they are in need
of a complete set of standards to support instrument calibrations for their existing continuous monitors
and the new proposed technologies. Quality control and quality assurance samples and support for the
network should be developed within the available laboratories but, should be supplemented from an
external source.
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TABLE C-1.
The Distribution of Air Pollutant and Meteorological Monitoring Sites by Gulf Nation.
Nation
Organization
Number of Air and Met Sites
SAUDI ARABIA
MEPA
3 fixed sites - meteorology and air pollution at different
locations of the same city
1 mobile site - meteorology and air pollution
1 fixed meteorology site
Saudi ARAMCO
8 air quality sites with meteorology
6 additional meteorology sites
Royal Comm.
Cluster of Five Stations in
for Jubayl
Jubayl
& Yunbo
KUWAIT
3 sites with continuous monitors (2 with power, 1
without power).
4 sites with Anderson samplers, high vols. and dustfall
buckets. (no power)
1 additional TSP site (no power)
6 additional dustfall sites
4 temporary S02 bubbler sites located at 4 hospitals
(some power)
BAHRAIN
JIM: PLEASE FILL IN
QATAR
3 mobile monitoring sites
IRAN
unknown
IRAQ
unknown
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The analytical laboratory at King Faud U.P.M. has recently been provided the above procedures
to permit a self assessment of their equipment availability to conduct these detailed analyses. Currently,
the K.F.U.P.M. is conducting experiments on PAH's analysis of high volume filters as a first step in this
program. K.F.U.P.M. has not had any experience with PUF, VOC canister analysis, or PM₁₀ sampling
and analysis. They have on hand the capability to expand their current analytical capability to provide
support to the proposed network.
The analytical laboratory of Saudi ARAMCO as with MEPA has had no experience in collecting
and analyzing particulate PM₁₀ samples, PUF, and canister samples for VOC speciation and PAHs.
In summary, the current level of technical competence within all of the facilities visited, MEPA,
King Faud U.P.M., Saudi ARAMCO, and Kuwait, indicates that upon the procurement of adequate
equipment, standards, and training, they all could support the sampling and analysis required for this
program.
A substantial number of meteorological measurement sites exist within the eastern provence of
Saudi Arabia and the nations of the Gulf Region. Most of those sites are along the shoreline of the Gulf.
ARAMCO operates 14 sites with meteorological data. Eight of those sites have collocated air quality
measurements. Three of those sites are over the Gulf waters on platforms or on an island. MEPA
(Saudi Arabia) has five sites with collocated air quality measurements. In addition, there are surface
observations collected at many of the airports throughout the kingdom. Surface meteorological data are
being collected at other Gulf region locations. Their locations may be identified through the WMO
publications. Previously, there were other surface measurement sites within Kuwait but their operational
status remain unknown at this time.
Two upper air balloon sounding sites are operating within Saudi Arabia. One site is at Dhahran
and the other is about 115 miles to the SW of Kuwait City at AI Qaysumah. Twice daily soundings are
collected at those locations, at 0000 and 1200 GMT. Prior to the war in Kuwait, twice daily upper air
soundings were made at the Kuwait International Airport. the resumption of those soundings could be of
substantial benefit to describing the airflow across the areas of Kuwaiti oil fires.
2.2 Meteorological Observations
The following summarizations are based upon first hand observations of the smoke plumes and
fires. Those observations were made during overflights and during vehicle traverses both within the oil
fields and along roads outside of the burning oil fields.
For any given day, the prevailing large-scale meteorological pattern will be the main driving
feature which determines where the smoke plumes will be located and how dense they will be.
Individual smoke plumes appear to act in manners typical of buoyant plumes from ground level
sources or plumes from short chimneys. Plume rise, the development of a bent-over plume geometry,
etc., seem to apply to the individual well-head fires; some have jets of fire and others are nearly surface
based burnings of the more combustible fractions of crude oil spread across the ground in the vicinity of
the well. Most of the fire plumes rise to between 500 to 1000 feet above ground level before becoming
mostly bent over, although some plumes have a significant amount of smoke remaining within a few
hundred feet of the ground.
Collectively, as groups of multiple fires within oil fields with a high density of burning wells
(particularly Greater Burgan), they assert a meteorological influence of their own. It is suggested that
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the grouping of fires with a horizontal diameter of 15 to 25 miles provides enough of an intense "heat-
island" that significant additional vertical rise of the smoke occurs inside the area. That additional plume
rise lifts smoke to elevations often 3000, 4000, to 5000 feet above ground within the initial few miles
downwind. Eventually, portions of the smoke rise even more, with multiple layers often forming at
heights up to 8000, 9000, even 12000 to 13000 feet. Between such layers and at the tops of layers
many tens of miles downwind, a generally diffuse and homogenous zone of smoke has been observed.
The eventual smoke height limits are bounded by the regional vertical temperature structure and
synoptic weather characteristics. Information reviewed to date suggest that those maximum heights are
mostly 8000 to 12000 feet within the initial 100 to 200 miles downwind from the Kuwaiti oil field fires.
With the creation of a local heat-island, a distinct inflow of near surface air has been observed
within the initial 500 to 1000 feet above ground level. At times, that inflow of wind is estimated to be 5 to
15 m/sec in strength. Smoke plumes at the peripheral bounds of the burn area tend to slant inward
toward the center of the burning field instead of pointing downwind with direction of the expected
ambient wind.
Local variations in daily wind flow, along with the fire-storm like winds, are likely to produce
preferred locations and times of day at which more concentrated smoke plume exposures reach ground
level. Prevailing winds are from the northwest throughout the year. During the daytime a sea breeze
can be expected to develop at the Gulf shoreline and progress inland as the day progresses. That
inflow of air can readily clear out the smoke plumes and yield substantially cleaner air at ground level on
the Gulf side. Along the leading edge of the sea breeze front there likely may be a zone of extended
and elevated exposures to fire effluent. That zone may well extend down the shoreline from Kuwait City
some 100 km. The area of greatest susceptibility appears to be to the southeast of fires in the AI
Ahmadi oil field (part of the greater Burgan field).
2.3 Data Base Management
In addition to evaluating the existing air monitoring networks, the Team made an initial review of
existing data systems to handle the air monitoring data. The previous meteorological, air quality, and
visual observations of the oil field fire plumes should be archived, along with data to be obtained during
the period of on-going Kuwaiti fires. A dedicated facility for the performance of that archiving does not
appear to exist. The data management task is likely to be a sizeable task and extended of a period of a
year and more.
Some of the general functional needs of the data management system include the following.
The data which will need to be assembled into the data base will likely come from many different
sources and exist in diverse formats and media. One role of the data base management activity will be
to assemble all information into a common, uniform structure. The second and equally important part of
the data archiving is the provisions of a uniform and consistent mechanism for the retrieval of data by
participating agencies. The degree to which that data base is well formulated, will significantly affect the
efforts of users of the data as they attempt to study and interpret the measurements.
A number of possible methods exist for the set-up of a computerized data base. Commercial
software and hardware of various degrees and complexity and cost exist which would satisfy the data
management needs. Before the choices of system software and hardware are made, the functionality of
the overall system and the manners in which users work with the data sets should be considered. For
example, it may be required that the data base be a "relational" data base. Other sources of software
that might be used to handle a large volume of data would be the U.S. Environmental Agency's (USEPA)
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Aerometric Information and Retrieval System. That system can handle hourly data and has considerable
software available to both summarize and analyze the ambient air data.
MEPA has asked the Team to recommend the type of computer and associated software
needed to manage the data collected in order to implement the monitoring plan. For now, it is more
appropriate to defer specific recommendations. A number of general performance characteristics may
be stated but specific details should be formulated in conjunction with data base specialists at a later
date.
RECOMMENDATIONS
While preliminary, the Team believes that the following recommendations should be implemented
based on our initial data gathering exercise. A general objective is listed as a recommended goal and
below that objective are listed several needed items or activities to facilitate the achievement of the
overall goal.
1. Objective: Provide a framework for an early warning advisory capability for areas expected to be
impacted by effluents from Kuwaiti oil field fires.
Needs:
a.
Meteorological data observations and forecasts
b.
Visual observations from key receptor areas
C.
Review existing monitoring data
d.
Calculate smoke trajectories and concentrations
2. Objective: Provide a cursory wide-area indication of the distribution and composition of the Kuwaiti
oil field fire effluents.
Needs:
a.
Establish 10 to 15 PM₁₀ monitoring locations using portable monitors.
b.
Train personnel in the operation of the portable PM-10 monitors and develop the
analytical support capability within Saudi Arabia and Kuwait.
C.
Define the PM₁₀ to TSP ratios.
d.
Define the composition of the plume by XRF analysis for limited organic
identification.
e.
Establish a central media preparation and analysis location.
f.
Define the baseline contribution of the ambient aerosol from the surrounding
desert.
3. Objective: Characterize the aerial smoke plume.
Needs: a.
Collect many of the same plume measurements recommended for the ground
monitoring array
b.
Collect descriptions of the width and vertical extent of the smoke plume at
several downwind distances
C.
Characterize the regional background by samples outside of the smoke plumes
4. Objective: Develop a more complete profile of the smoke plume constituents
Needs: a.
Procure equipment for a limited number of comprehensive air quality monitoring
stations to collect: TSP, PM₁₀, organic, and inorganic constituents
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b.
Establish a limited number of comprehensive air quality monitoring stations to
collect: TSP, PM 10' organic, and inorganic constituents. These should be
collocated with the continuous monitors wherever possible.
C.
Train individuals to operate and maintain the sampling instrumentation in
support of the monitoring program
d.
Procure the necessary analytical laboratory equipment required for analyses of
the samples collected under this objective
e.
Train laboratory personnel in the preparation of the sampling media, QA/QC
procedures required and the subsequent sample analytical procedures.
5. Objective: Determine the need for expansion of the monitoring network to a wider regional
coverage.
Needs: a.
Review the data developed from the limited network.
b.
Assess the current and projected status of control of the oil field fires and
emissions.
C.
Review the population health survey statistics.
d.
Review the suitability of the sampling strategy, and modify where needed
e.
Expand the limited network as the situation requires, data analysis indicates an
additional need for data, the response of the affected populations indicate, or
the model requires additional parameters.
Many of the same considerations listed for air quality above also apply to meteorological
considerations.
6. Objective: Provide a meteorological data stream to facilitate the modeling and prediction of areas
expected to be impacted by effluents from Kuwaiti oil field fires.
Needs:
a.
Upper air balloon sounding data representative of the Kuwaiti oil field fire area
and Gulf region plume transport.
b.
Supplemental surface based measurements of wind speed and direction,
temperature, moisture content of the air (dew point, relative humidity, etc.), solar
radiation, atmospheric pressure, precipitation.
7. Objective: Provide a meteorological data set to investigate the areas of climate modifications
occurring due to effluents from Kuwaiti oil field fires.
Needs:
a.
Supplemental surface based measurements diffuse and direct solar radiation.
b.
Special collections of precipitation throughout the region to examine the pH and
chemistry of the rains.
C.
Aircraft soundings and profiles of smoke, winds and temperatures, air quality
related measurements of plume compositions and concentrations representative
of the Kuwaiti oil field fire area and Gulf region transported plumes.
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4. PHASED AIR MONITORING PLAN
This section of the report discusses a prioritized plan of stepwise incremental actions for the
phased implementation of the recommendations discussed above. Five phases for implementing the
plan follow.
4.1 Phase 1. Provide a Framework for an Early Warning Advisory
In order to accomplish this task, the following action items need to be initiated or incorporated
into the task framework.
1.
Gather daily weather forecasts to predict meteorological conditions which would effect
pollution potential in both Saudi Arabia and Kuwait.
2.
Use visual observations from key receptor sites to determine possible pollution levels.
3.
Gather existing air monitoring data from fixed and mobile sites operated by MEPA, Saudi
ARAMCO, and the governments of Kuwait and Bahrain to develop a data base of
existing data.
4.
Establish a daily briefing for representatives of the many entities concerned with
behaviors and fate of the aerial effluents from the oil field fires in Kuwait.
5.
Develop a daily map depiction of the aerial distribution of the smoke plumes across the
region using satellite imagery, for each day since initiation of the oil field fires.
6.
Issue a daily general statement about the expected behavior(s) of the oil fire plumes.
Areas of potentially adverse conditions could be treated as locations for which
advisories would be issued.
7.
Provide forecast meteorological conditions across the region for the next 2 to 3 day
period, including the expected location(s) of the smoke.
8.
Obtain data from the MEPA network throughout the eastern province.
9.
Direct the crews of the SLAR aircraft, (USCG Falcon Jet), to continue on a regular basis
the present visual observation and mapped notations concerning the horizontal extent of
the smoke plumes and the estimations of altitudes of layer bases and tops.
10.
The above information could be compiled initially in hard copy form. Later it should be
stored on electronic media in a way that an existing PC data management system could
readily incorporate it.
4.2
Phase 2. Establish a PM₁₀ Monitoring Network Using Portable PM₁₀ Monitors.
Working in conjunction with the Saudi Arabian Meteorology and Environmental Protection
Agency (MEPA), the proposed plan has been developed to collect information on PM₁₀, which
represents particulate matter with particulates less than 10 microns in diameter. At the present time
there is no PM₁₀ monitoring in the Gulf region.
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OBJECTIVES
The objectives for this effort are as follows:
1) Determine the magnitude or the health threat to residents of population centers and field-
based military personnel impacted by the oil field fires and typical sources (windblown desert
soils).
2) Establish a scientifically based capability to alert these affected populations prior to the onset
of the potential health threats from real-time measurements.
3) Establish a technical basis for executing predictive air quality dispersion models which
simulate the oil well fire emissions, background sources, and consequent impacts over space
and time.
4) Establish a regional network of PM₁₀ stations using a consistent monitoring methodology
across the countries of Saudi Arabia, Kuwait, and Bahrain.
5) Train personnel to operate and analyze the media produced by the network from each of the
participating countries.
6) Develop a regional data base and encourage the sharing of data developed from the network
with all participants.
The above objectives convert the foregoing goals into discrete actions:
1) Determine the spatial temporal frequency, and severity of the impact to the resident
populations and military centers affected through the application of saturation sampling
techniques with portable PM₁₀ samplers.
2) Establish the correlation of real-time surrogate monitoring data to date generated from direct
sampling methods through the collocation and simultaneous operation of both methods over
time.
3) Where possible use impact data collected from samplers as an input to the dispersion model,
run the model "backwards" to develop a better estimate of the emission rates of the fires and
produce a higher level of confidence in the predictive modeling results.
4) Obtain from the literature and/or develop from source sampling analysis chemical profiles of
all major pollutant sources in order to:
a) identify those contaminants that pose the greatest health concerns and to develop
an estimate of acceptable ambient levels (AALs) prior to the conduct of field work,
b) identify the chemical "signature" of the major contaminants and other tracers
characteristic of the primary sources,
c) enable apportionment of these contaminants and other tracer compounds from a
simple total mass concentration measured by the ambient samples, and
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d) attempt to relate these levels in turn to the surrogate real-time monitoring methods
for use in issuing timely health risk alerts.
5) Ensure that the data generated by the network are of a demonstrably high quality (precision
& accuracy), completeness, representativeness, and comparability.
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TIME
POSITION
BASE/TOP
WIND
(LAT/LONG)
(DIR/SPD)
0545
N2623E50-31
CLR VIS 15 M
332/23
0600
N2700E4958
CLR
321/19
0615
N2744E4916
CLR
300/20
0630
N2822E4839
TOPS 070/030
331/008
0645
N2918E4819
SMOKE 060/030
335/10
0700
N2932E4810
SMOKE 070/030
344/10
0715
N29344830
SMOKE 070/030
265/7
0730
N29354857
THIN SMOKE 050/030
215/6
0745
N2925E4920
VERY THIN SMOKE 090
133/003
0800
N2833E4945
THICKER SMOKE 090/ 080
326/006
0815
N2738E5035
THIN SMOKE 090/080
280/005
0830
N2702E5111
SMOKE 090/060
192/010
0845
N2625E5148
SMOKE/HAZE 080/060
215/12
0900
N2618E5118
SMOKE/HAZE 070/SURF
230/009
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APPROACH
Conduct a PM₁₀ saturation sampling study for the determination of the temporal and spatial
features of the impact of the oil well fires and attempt to reconcile the data with existing model
estimates. PM₁₀ mass concentrations would be available within 24-48 hours following sampling. No on-
site meteorological, gas, or aerosol monitoring or chemical analysis is required (chemistry could be
attempted later on the preserved media). One or more portable nephelometers would be collocated at
several sampling sites to develop correlations between manual and continuous (real-time) methods for
alert advisories.
A total of 15-20 portable PM₁₀ samplers equipped with quartz filters would be run simultaneously
on a daily basis or "triggered" (impact forecast) basis throughout the study area. Network design would
involve a "nested" approach to address the objectives:
1) samplers sited at background locations (not impacted) by the smoke plume and samplers in
populated areas.
2) samplers in populated areas impacted by smoke.
Samplers could be "ganged" (2 or more) and programmed to run consecutively at individual
sites if filter clogging problems occur because of high loading. Further, multiple samplers could be
collocated at certain sites to collect fine particulates (less than 2.5 microns) and coarse particulates (2.5-
10 microns) on teflon sample filters (facilitating XRF elemental analysis). One of the 10-12 sampling sites
would be equipped with duplicate samplers in an effort to develop sampling precision estimates.
This comprehensive program will yield the following:
1) short turnaround PM₁₀ concentrations,
2) gross estimates of the fire-specific contributions to total mass could be derived by
subtracting background concentrations from the impact site concentrations,
3) applying assumptions on the source profiles to pollutant loading attributable to the well fires,
estimates of individual target compound loadings could be computed and a comparison to AALs
made,
4) correlations factors can be determined between real-time surrogate methods and manual
methods, and
5) impacted sampling media would be available for subsequent intensive chemical analysis in
an attempt to reconcile assumed source signatures and extracts can be used to perform any
other analytical tests (mutagenicity). Special precautions may be needed to preserve the sample
integrity during storage and transfer.
Limitations: no on-site meteorological data to calculate emissions rates, no on-site chemistry
(unless developed) to confirm critical assumptions, and no concurrent gas or acid aerosol
measurements to evaluate or correlate with the particulate data.
Resources: 1-2 professionals, 1 field technician per site, if it must be operated individually
(actual number contingent upon the network logistics and potential "clogging" implications), portable
PM₁₀ saturation samplers, portable nephelometers, lap-top computer, microbalance, expendables and
sundry support gear.
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In summary, this approach is PM₁₀ mass data-rich, and assumption rich and in contrast to being
reconciliation and broad pollutant characterization-poor.
SAMPLING AND ANALYTICAL METHODS
The alternate approaches identified above involve the use of a variety of sampling and analytical
methods summarized below:
Portable PM₁₀ Saturation Samplers
-
segregate and capture of filter, particulates of 10 micron size (respirable particles) and
smaller.
-
battery-operated, lightweight, rugged, inexpensive, small, and quiet.
-
easily deployed and operated.
-
programmable timer for unattended on and off.
-
rechargeable battery packs.
-
continuous operation up to 30 hours on a single charge.
-
precise and accurate.
-
low detection limit of approximately 5 ug/m3
-
sustained operation under high particulate loadings, e.g. 100 ug/m3 or more.
-
electronic sample flow regulation.
-
electronic sample flow totalizer.
-
low flow shutoff/warning.
-
can accept a variety of other pollutant sampling media (e.g. PUF, DNPH, charcoal,
denuders, etc.) or take whole air samples (Tedlar bags) with little or no modification.
Portable nephelometers
-
many of the same attributes of the PM₁₀
-
battery operated
-
effectively measure particulates of 1 micron diameter or smaller.
-
continuous reading, storing five minute averages.
-
rechargeable.
-
continuous operation from 2-48 hours on a single battery charge.
-
internal storage for up to nine days of sampling data.
-
data download to a portable lap-top computer through RS232 serial port.
-
operationally equivalent to standard nephelometers.
Microbalance
-
five to six place balance.
-
rugged, transportable while precise and accurate.
Field XRF Unit
-
similar MQLS with situ laboratory units.
-
rugged.
Support Gear
-
calibration and audit gear, tools and diagnostic equipment, etc.
PROPOSED NETWORK DESIGN
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The recommendation for siting of the portable PM₁₀ samplers is predicated on providing a large
area of coverage for developing a better estimate of the areas impacted by the plume, a cross-sampling
of population and troop centers, and to a capability to provide a technology transfer to Saudi Arabia,
Kuwait, and Bahrain.
SAUDI ARABIA
-
collocated site at K.F.U.P.M. (2 sites)
-
two sites in Riyadh (1 U.S. Embassy & 1 MEPA location)
-
one site Royal Commission at Jubayl
-
one site Saudi ARAMCO at Tanajib
-
one site MEPA at Khafji
Total of seven (7) sites.
KUWAIT
-
three sites (3) located at the two operational continuous monitoring sites within Kuwait
City (one site collocated)
-
one site at Camp Freedom
-
One site U.S. Embassy
-
One site AI Hamadi (Kuwait Oil Company Hospital)
Total of six (6) sites.
CENTCOM
-
two sites at selected troop locations
Total of two (2) sites.
BAHRAIN
-
one site to be determined
Total of one (1) site.
A total of sixteen samplers are committed to field sampling with the remainder as spares or as
changes to the sampling plan requires.
Phase 3. Characterize the Aerial Plume.
This phase should follow closely with Phase 2, in order to characterize the 3-dimensional nature
of the smoke plumes from the fires in Kuwaiti oil fields. To achieve that goal, many of the same plume
measurements collected by the existing and proposed ground level measurement locations should be
provided by the aerial sampling platform. Obviously, the longer time integrated samples (e.g., 24 hour
total values, averages, etc.) cannot be reproduced by aircraft borne devices. Short-term and across
plume integrated measurement descriptions may be obtained to characterize the special extent and
details of actual constituents of the elevated portions of the oil fire plumes.
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The aerial sampling activities may be separated into measurements which address the three
general zones of plume characteristics, from an a meteorological sense. Those zones are the 1) close-
in zone, 2)intermediate or transition zone and 3)extended or distant zone. Measurements very near the
wellhead are difficult to impossible to obtain due to excessive heat and great levels of turbulence.
Measurements at intermediate distances will be difficult and many locations within the
clustered groups of burning wells may be unsafe for aerial traverses due to the extremely dense smoke
and hidden turbulent plumes. Measurements at the longer distances, a few miles downwind of the
burning wells, should be possible. Measurements from a few to several hundred miles downwind of the
fire area should be feasible. Within that distance range the approximate concentrations, plume
dimensions, and estimated mass flux in the downwind directions may be approximated. The aerial
sampling strategies should concentrate on the obtaining of those types of information.
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4.4
Phase 4. Develop a Complete Profile of the Smoke Plume Constituents.
Obtain additional equipment to expand existing continuous monitoring high priority sites in
Kuwait and Saudi Arabia
The survey conducted by the Team during Phase 1 of this plan indicated that within the region,
respirable particulate sampling technology, aerosol and total particulate sampling and analysis for
volatile organic compounds (VOC), semi-volatile organic compounds (SVOC), and PAHs were either not
available or insufficient to properly characterize the effects of the oil well fires on the population centers
and the troop concentrations within the region.
This phase of the plan proposes to bring into the region several new technologies and to train
personnel withn the region to operate samplers, to condition, and analyze the several new media
necessry to support this expanded network. The objective of this process is to develop a stand-along
capability within each participating country for aerosol and particulate monitoring which will support the
Gulf regional air quality characterization and index plan outlined in Phase V.
During this phase of the plan the Team proposes to expand the continuous air and
meteorological monitoring currently being conducted within the region at six sites. These sites are
recommended based on the need to jointly develop the sampling and analytical capability within the
region to ensure that it becomes self-sufficient and sustainable. The particular technologies outlined
below are not currently operated within the rgion nor are the analytical procedures required to support
them currently being utilized. However, the Phase I survey indicates that with sufficient training,
additional equipment, and some experience with actual field samples the transfer should be relatively
smooth.
Initially, the Team's recommendation of six sites strategically placed along the axis of the area of
greatest impact by the oil well fire plume will generate sufficiaent samples for the required training, while
also providing critical data not currently being collected by the existing networks or available through the
portable PM₁₀ network proposed in Phase II. As this data base develops it can be used to better define
the constituents of the plume and thus permit a more accurate assessment of the potential long-term
health risk.
The equipment listed below should be collocated with the full compliment of continuous air and
meteorological monitors described in Phase V at these six proposed sites. A brief description of the
equipment is provided below:
TSP High Volume Sample used to collect a 24-hour sample of the total suspended particulates,
operated nominally at 50 OFM, and typically uses 8x10 inch glass fiber, quartz, or teflon filter
media.
PM₁₀ High Volume Sampler - used to collect a 24-hour sample of the 10 micron and smaller
sized fraction of the total suspended particulate sample collected by the TSP sampler above,
sampler is typically operated at 40 CFM, and utilizes an 8x10 inch Quartz or teflon filter media.
Note: glass fiber media should not be used if there is concern for a known sulfate artifact
formation problem.
PM₁₀ Manual Dichotomous Sampler - used to collect a 24-hour sample of the 10 micron
particulate size fraction of the TSP, sampler operates at 16.7 liters/minute, and utilzes two (2) 37
mm diameter Teflon filters to collect a fractionated sample with a cut point of 0-2.5 micron (fine
fraction) and 2.5 10 micron (coarse fraction).
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VOC Canister Sampler - used to collect up to a 24- hour integrated whole air sample in six-liter
evacuated stainless steel canisters, interior walls are passivated to minimize sample degradation,
samples volume can be rgulated by either limiting the volume to ambient pressure or pumping in
addition sample to an approximate volume of 16 liters, these samples can be used for the
determination of total hydrocarbons or analyzed for specific hydrocarbons, multiple analysis are
available from a single pressurized canister sample. Note: An extensive canister cleanup
process is required prior to the collection of additional air samples.
Polyurethane Foam (PUF) Low Volume Sampler - used to collect 24-hour aerosol samples
utilizing small AC or battery operated pumps at flow rates less than five liters per minute on
relatively small glass cartridges containing a PUF plug, these samples can be extracted and
analyzed for PAHs, or other SVOCs. Note: Both the glass cartridge and PUG plug require an
extensive cleanup procedure prior to re-use.
Optional Tenex/Charcoal/XAD-2 tubes - these media can be used with same type of low volume
pumps described above to collect additional samples for further definition of the constituents of
the plume for SVOCs.
Organic compounds will be present in all three phase distributions (particle bound, SVOC, and
VOC) and each phase will have to be sampled and then a determination will have made as to
importance of each.
The particle bound is phase can be collected [something missing?] for extractible organic
analysis from both quartz, teflon impregnated glass fiber gilters, or teflon.
The SVOC phase can be collected on PUF and within the canister. The VOC phase can be
collected with canisters and charcoal tubes. Employment of Tenex and SAD-2 sampling tubes in
conjunction with PUF, charcoal tubes, and canisters in an overlapping sampling matrix, can be used to
confirm of the presence or absence of compounds which could be missed by a less complex sampling
matrix.
Proposed locations for the initial six expanded sites:
The Team recommends that the six locations follow the general axis of plume drift from Kuwait
City south into Saudi Arabia. It is further suggested that the operation of these sites be divided amongst
the key network managers within the two countries: Kuwait, MEPA, and Saudi ARAMCO. This division
of respnsibility supports the philosophy to jointly develop both the sampling and analytical capability
within all three entities.
Kuwaiti Locations
The Team recommends that two (2) of the sites be located at the existing operational
continuous monitoring stations located in Kuwait City. A third site should be established in Al-Abmadj at
the Kuwaiti Oil Company Hospital. This location is situated within 300 400 meters of several burning
wells and is adjacent to the closest residential area associated with any of the oil fields.
Saudia Arabian Locations
The Team recommends that a site be established at King Fahd University of Petroleum and
Miners (K.F.U.P.M.) in Dharhran, one site to be collocated with Saudi ARAMCO site in Tanajib and the
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last site should be collocated with the MEPA sie in Khafji which currently is only collecting meteorology
data.
Episodic/EARLY WARNING measurements
Longer term monitoring
PM₁₀
(continuous)
Acid aerosols
TSP
VOCs
SO2
(continuous)
Aldehydes
O3
(continuous)
BaP, other PAHs
NOx, NO
(continuous)
Trace elements
CO
(continuous)
Fine particles
H2S
(continuous)
3.
Health Monitoring Survey
Air monitoring data collected through the proposed air monitoring network will provide basis for
interpreting the results of health surveys of the populations and ecosystems potentially effected by the
effluents from the oil fires in Kuwait. The kinds of health data that could be collected include:
Health questionnaires
Blood samples
Hair samples
In-vivo animal studies
Forced expiratory volumes
Other morbidity parameters
Distribution of Proposed and Existing Air Monitoring Sites
Table 2 shows the location of the existing and proposed air monitoring sites, while Table 3 lists
the locations of the proposed air monitoring sites. In order to complete the network in an orderly
manner, it is proposed that the network be developed in several stages. The first order of business
would be to upgrade the existing monitoring locations so that there exist a full complement of air and
meteorological monitoring equipment, as well as add new critical air monitoring stages (Stage 1). The
second stage would be to establish those sites that would satisfy the minimum requirements for tracking
the plume caused by the oil fire and to provide an early warning system for Saudi Arabia, Kuwait, and
Bahrain (Stage 2). The third and final stage would be to complete the final network following a review of
the quality and quantity of findings to date (Stage).
5.
SUMMARY
The initial measurements made by the Team suggest that there is not an imminent threat from
SO2 and H2S to the urban populations, while short term measurements of particulate are frequently
high. Historically, this region has high particulate levels due to wind blown dust. The particulate
measurements that were collected by the Team reflect total particulate, as opposed to respirable
particulates, that is PM₁₀. There has not been a principal focus in the Region on total particulate,
PM10 and organics up to now. Therefore, the Team developed the five phased monitoring plan with
an emphasis on better understanding particulates and the aerosol organics associated with the oil fires
in Kuwait. Particulates and organics could be a source of concern for both health and ecological
effects.
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The air monitoring proposals presented in this report represent the Team's collective judgement
on what needs to be done. Those judgements are based upon an on-site evaluation of the situation in
Kuwait, discussions with officials from the Saudi Arabian MEPA, Kuwait, Saudi ARAMCO, and the King
Faud University of Petroleum and Minerals. Needless to say more work is needed regarding data
management, statistical design, data analysis and quality assurance. Because of the complexity and
immediacy of this problem, an extended time commitment will be needed on the part of all Gulf nation
agencies to achieve the objectives outlined in this report.
Cost estimates for the various tuypes of air and meteorological monitors are attached to this
plan, along with documentation on the U.S. Environmental Protection Agency's Pollutant Standards
Index (PSI).
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TABLE 2. Location of existing air and meteorology monitoring stations
NATION
ORGANIZATION
LOCATION
STAGE OF
IMPLEMENTATION
EXISTING
SITES
Saudi Arabia
MEPA
Damman
1
Hofuf
2
Tanagib (Mobile Site)
1
Riyadh
1
Khafji (Met Only)
1
Udayliyah
3
Shedgum
3
Abqaiq
3
Dhahran
2
Tartut
2
Rahimah
2
Juaymah
1
Tanajib
1
Saffaniyah Oil Field
3
(met only)
Marjan Oil Field (met only)
3
Farisiyah Island (met only)
2
The Royal Comm. for
Cluster of 5 stations
1
Jubyayl and
in Jubyayl
Yunbo
Existing Sites:
SITE 1
1
Kuwait
SITE 2
1
SITE 3
1
Existing Sites:
3 mobile units, unknown locations
2
Qatar
TABLE 3. Location of proposed air and meteorology monitoring stations
NATION
ORGANIZATION
LOCATION
STAG
E
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Proposed Sites:
Saudi Arabia
MEPA
Awiyah
3
Shumlul
2
Sarrar
2
Nuayriyah
2
Lisafah
3
Uafar al Batin
1
28 deg 6 min latitude, 47 deg 51 min longitude
2
28 deg 30 min latitude 48 deg 1 min longitude
1
28 deg 55 min latitude 47 deg 32 min longitude
2
29 deg 7 min latitude 46 deg 39 min longitude
2
Kuwait
Mina Saud
1
U.S. Embassy
1
AI Ahmadi
1
(Hospital)
International
1
Airport
29 deg 23 min latitude 46 deg 55 min longitude
2
29 deg 50 min latitude 47 deg 15 min longitude
2
30 deg 4 min latitude 47 deg 42 min longitude
2
29 deg 33 min latitude 47 deg 50 min longitude
2
Bahrain
Manamah
2
Qatar
Dawhah
2
United Arab Emirates
Aub Dhabi
3
Dubai
3
Oman
Muscat
3
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