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000554

CIVIL ENGINEERING LABORATORY
Naval Construction Battalion Center
Port Hueneme, California 93043

Technical Note N-1353

THE FATE OF SPILLED NAVY DISTILLATE FUEL

By

Peter J. Hearst, PhD

September 1974

Sponsored by
Naval Sea Systems Command (Sea OOC)

Approved for public release; distribution unlimited.

|S Se

.

Pit

Unclassified
SECURITY CLASSIFICATION OF THIS PAGE (When Data Entered)

REPORT DOCUNENTATION PAGE

T. REPORT NUMBER 2. GOVT ACCESSION NO} 3. RECIPIENT'S CATALOG NUMBER
TN-1353

4. TITLE (and Subtitle) 5S. TYPE OF REPORT & PERIOD COVERED

THE FATE OF SPILLED NAVY DISTILLATE Final; July 1972—June 1973

FUEL 6. PERFORMING ORG. REPORT NUMBER

7. AUTHOR(s) amr) CONTRACT OR GRANT NUMBER(s)

Peter J. Hearst, PhD

lL.

9. PERFORMING ORGANIZATION NAME AND ADDRESS 10. PROGRAM ELEMENT, PROJECT, TASK

CIVIL ENGINEERING LABORATORY Se ta ma cia
Naval Construction Battalion Center 52-028
Port Hueneme, California 93043

11. CONTROLLING OFFICE NAME AND ADDRESS 12. REPORT DATE

Supervisor of Salvage (Sea OOC) September 1974

13. NUMBER OF PAGES

Naval Sea Systems Command 28

14. MONITORING AGENCY NAME & ADDRESS(if different from Controlling Office) 15. SECURITY CLASS. (of this report)

Unclassified

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DISTRIBUTION STATEMENT (of this Report)

Approved for public release; distribution unlimited.

DISTRIBUTION STATEMENT (of the abstract entered in Block 20, if different from Report)

SUPPLEMENTARY NOTES

- KEY WORDS (Continue on reverse side if necessary and identify by block number)

Distillate fuel on seawater, oil spills on seawater, fuel oil on seawater, simulated
weathering of oil spills, gas chromatography, evaporation of spilled oils, oil slick
dissipation.

ABSTRACT (Continue on reverse side if necessary and identify by block number)

Laboratory weathering studies of four Navy distillate fuels on salt water showed
that in thick films (5 mm) the major portions of the oils (75 to 90%) did not evaporate
in one week. These fuels are thus relatively persistent oils. The physical properties did
not change markedly and the thick emulsion, or mousse, obtained with Navy special
fuel oil was not obtained with the distillate fuels. Very thin films (0.1 mm) evaporated

continued

DD , pone 1473. EDITION OF 1 Nov 65 IS OBSOLETE

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20. Continued

much more rapidly, leaving residues of about 5%, whereas Navy special fuel oil left
residues of 65%. The weathering characteristics are related to the distillation range
as shown by gas chromatographic comparisons.

Unclassified

SECURITY CLASSIFICATION OF THIS PAGE/When Data Entered)

CONTENTS

INTRODUCTION

EXPERIMENTAL WORK

Properties of the Fuel Oils

Evaporation of Thin Oil Films

Simulated Weathering of Oils on Seawater

DISCUSSION

General Considerations . 6 .

Evaporative Losses .

Dissolution and Dispersion . 6

Changes in Viscosity

CONCLUSIONS . 3 : : 0 : 6

ACKNOWLEDGMENT

REFERENCES : 0

APPENDIX - Determination of Oil Evaporation by Gas Chromatography

14

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INTRODUCTION

As the Navy is changing from the use of Navy special fuel oil
(NSFO) to the use of Navy distillate fuel it becomes more important
to know the fate of distillate fuel when it is spilled at sea. Of
particular interest are the persistence of the oils at sea and the
properties and changes in properties that are related to the removal
of the oil by man or by natural means.

The general changes that take place in crude oils on the open
sea are known [1]. Evaporation and dissolution studies of several
fuel oils have been reported recently [2]. Comparatively little specific
information is available about the weathering of Navy distillate
fuel. The distillate fuel is expected to evaporate faster than the
NSFO and is expected not to become as viscous as spilled NSFO, but
how great these differences are is not known. The lack of color will
make recovery operations more difficult. An investigation at the Civil
Engineering Laboratory* (CEL), Naval Construction Battalion Center,
Port Hueneme, CA, was, therefore, sponsored by the Navy Supervisor
of Salvage.

Samples of various Navy distillate fuels and of NSFO were subjected
to simulated ocean weathering in the laboratory. The results of this
investigation are presented in this report.

EXPERIMENTAL WORK
Properties of the Fuel Oils

Five fuel oils were obtained for the experiments. Four of these
were Navy distillate fuels, which were designated Fuel Oils A, B,
C, and D; the fifth was a Navy special fuel oil, designated Fuel
Oil E. Some of the properties of the distillate fuels and the corresponding
specification values [3], with degrees Fahrenheit converted to degrees
Centigrade, and with API gravities also listed as specific gravities,
are shown in Table 1.

The colors of the fuels ranged from a light brownish amber (1.0)
to a dark reddish brown (3.5). The reported crude sources were: Oil
A - 100% Arabian Crude; Oil B - 30% Southern California Regular, 14%
Torrance and Wilmington, 20% Inglewood, and 36% Segregated; Oil C - 79%

2 Formerly Naval Civil Engineering Laboratory.

Table 1. Selected Properties of Distillate Fuels

Properties Specifications

Viscosity,
Kinematic,
ale See CGO) .
centistokes

10.0 maximum

Density, at 16°C
(60°F):

Specified Gravity 0.893 maximum

API Gravity 27 minimum

Color, ASTM

Distillation, °C

10% maximum
50% maximum
90% maximum
95% maximum

Cal-Mix, 21% Murban; Oil D - 35% Los Angeles Basin, 23% Light Mix
(Northern Galtronniaye and 42% Iranian.

The NSFO had a much higher viscosity of 48 cs (at 122°F or 50 Se
its specific gravity was 0.984 and its API gravity 12.33; it was black;
and it was of unknown prior history.

The distillate fuels were subjected to gas chromatography to
determine the approximate boiling point distribution of the fuel
components. The gas chromatographic analyses were made according
to ASTM D 2887-70, using conditions similar to those proposed by
R. E. Kreider [4]. Dual 10-ft, 1/8 in., stainless steel columns with
10% OV-101 on 80/100 mesh CheeneseED ow (AW-DMCS) were used. The tempera-
ture was programmed from 75°C to 325°C at a rate of 8° per minute
with a 3-minute post-injection delay and a 12-minute upscale delay.
The injector temperature was 300° C, and the hydrogen flame detector
temperature was 350°C. Samples of about 3 microliters were used with
helium flow at 40 ml per minute and an attenuation of 103 x 16. The
positions of the normal alkanes were identified by comparison with
a chromatogram of a distillation calibration sample.

As is evident from the gas chromatograms shown in Figures la, 2a,
3a and 4a, Fuel Oil D had the highest proportion of low boiling components,
whereas Fuel Oil C had the lowest proportion of low boiling components.
All of the distillate fuels had negligible components with more than
about 22 carbon atoms. Fuel Oil C had a very narrow boiling range; it
not only had the lowest proportion of low boiling components, but
it also had the lowest proportion of high boiling components, which
included very little material with over 20 carbon atoms.

Evaporation of Thin Oil Films

Samples of the fuel oils were put into flat weighing dishes
and these were placed in a current of air and were weighed periodically.
The fifty-milligram samples of the oils, with specific gravities
of about 0.85, have volumes of about 59 microliters; and in dishes
25 mm square, these should form films slightly under 0.1 m thick.
The dishes were placed at the opening of a partly closed fume hood
and they were rotated after each weighing to provide nearly equal
exposure for each oil. The temperature of the room was approximately
25°C. The percentages of the oils remaining are shown in Table 2,
and are plotted in Figure 5.

Table 2. Evaporation of Thin Films

Percentage of Oil Remaining After
Fuel Oil

Simulated Weathering of Oils on Seawater

The simulated weathering was performed in a 12-liter three-
necked flask filled to the halfway mark with 6 liters of 3% aqueous
sodium chloride. The apparatus is shown in Figure 6. The diameter
of the flask was 29 cm, and therefore the surface area of the salt
water was 660 sq cm. A weighed 330-ml portion of the fuel oil was
added to provide a 5-mm layer of oil.

Air was supplied, at a flow of 6 liters per minute, through
an inlet tube reaching near the bottom of the flask. This air was
first freed of oil by filters and was saturated with water by a fritted
glass bubbler. Wind was provided by a paddle 15 cm wide and 4.5 cm
high, suspended above the oil layer and rotated at 600 rpm. The circum-
ference of the paddle was 47 cm. Since one mile per hour is 44.7
cm per second, one revolution per second provides a speed of about 1
mile per hour at the paddle tip. At 600 rpm, the wind speed at the
paddle tip was thus about 10 miles per hour.

A preliminary run was made with Fuel Oil C. This run was allowed
to progress for 44 days, during about 15 of which the stirring motor
was inoperative, and no wind was produced. All the other weathering
experiments were run for 7 days, with wind. One exception was a second
weathering of Oil D which was performed without wind.

At the completion of each run, the distillate fuel oil and the
water were allowed to separate for several hours. The bulk of the
weathered oil was then syphoned off through a glass tube, which was
inserted in one of the necks of the flask. This tube was flared at
the bottom and barely touched the surface of the oil. A slight vacuum
was used to lift the oil out of the flask and transfer it into a weighed
bottle. The bulk of the salt water was then removed from the flask
through the air inlet tube. A vacuum was applied, and the salt water
was collected in a filter flask. The remainder of the oil and water
was mixed with hexane, and the resulting hexane solution was washed
with water and evaporated. The evaporation of the hexane was completed
by placing the flask containing the oil into a water bath at 80°C
and passing 400 ml per minute of dry nitrogen through the oil for 1
hour after escaping vapors of hexane were no longer visible.

The weathered NSFO did not coalesce well and could not be syphoned
off. It was recovered by decanting repeatedly over a period of several
days until no more salt water separated. The residual oil and water
mixtures were extracted with dichloromethane, and the dichloromethane
solution was washed and evaporated in the water bath under nitrogen
flow.

The amounts of original and recovered oil are shown in Table 3.

The weathered distillate fuels were subjected to gas chromatography
under the same conditions described above (under Properties of Fuel Oils).
The chromatograms obtained for the four fuel oils after 1 week of
weathering with wind are shown in Figures 1b, 2b, 3b and 4b.

Table 3. Weight Changes During Weathering

Weathered Oil (gm)

Percentage
Recovered

Original
Oil (gm)

Ext racted
41.3

Syphoned

268.8 80.

68.2

We

90.

Hilo

87.

74.

926

x = Weathering without wind.
y = Preliminary 6-week experiment.

Oceparated by decanting.

The areas of the curves were measured with a disc integrator.
The total areas and the areas above a boiling point of 298°C are
shown in Table 4; also shown are the calculated portions remaining
after weathering and the percentages of oils recovered as given in
Table 3.

The viscosities of the oils were determined with a Zeitfuchs
Cross-Arm viscometer held in a bath at 22.2°C (72°F). For the distillate
fuels a Number 2 viscometer was used. For the NSFO a Number 4 viscometer
was used. The viscosity changes are shown in Table 5.

Total organic carbon analyses of the salt water extracts were
made. The values obtained for the aqueous layers from the weathering
of the oils are shown in Table 6.

DISCUSSION
General Considerations
Many factors will affect the fate of fuel oil spilled on the

open sea: wind; agitation; temperature; sunlight; micro-organisms;
presence of foreign matter; and, of course, the composition of the

Table 4. Oil Remaining After Weathering

(Calculated from gas chromatographic data and
compared with the weight percentages recovered)

Integrated AreaP 3
Portion

Recovered

Above 298°C Remaining Oil
A (P)° (%)
(A,)

= original.
w = weathered.
x = weathering without wind.
y = preliminary 6-week experiment.

b Disintegrator count.
© Calculated from P = (AY/A®)(AQ/AW)

Table 5. Viscosity Changes During Weathering

Viscosity at 22.2°C (cs)

Viscosity Recovered

i Oil
Original Oil Weathered Oil ae (%)

4 x = Weathering without wind.

Table 6. Carbon Content of Aqueous Extracts

Fuel Oil? Total Carbon Inorganic Carbon Organic Carbon ;
(ppm) (ppm) (ppm)
1.1

1.1

1.5
0.7
2.6
1.3

4 y = Preliminary 6-week experiment.

fuel oil. The changes that will take place in the oil include the loss
of light components by evaporation and the loss of constituents by
dissolution or dispersion. Chemical changes caused by oxidation or
photodegradation can produce oxygenated compounds, volatile products,
and condensation products; and additional chemical changes can result
from biodegradation. The presence of polar products and heavier components
may produce emulsification, and heavier components combined with
foreign matter may produce settling. Spreading will produce thinner
films in which all the above processes may be speeded up.

Chemical decomposition of distillate fuels, including decomposition
by microorganisms, is a comparatively slow process. Although chemical
or biological processes may be effective in removing final traces
of dispersed fuels, they are not expected to contribute materially
to the removal of the bulk of the oils. Dissolution is also expected
to be a minor factor in oil removal because of the very low solubilities
of hydrocarbons in water.

The chief method of loss of oil over a relatively short time
span, of perhaps a week or less, is expected to be by evaporation.
The rate of evaporation will depend on the vapor pressure of the
oil, on the thickness of the oil, on the temperature, and on the
wind speed.

Vapor Pressure. The vapor pressure of fuel oil depends on the
components that are present. The hydrocarbons with the lowest number
of carbon atoms have the lowest boiling points and the highest vapor
pressures. As the numbers of carbon atoms of the hydrocarbons increase,
the boiling points increase and the vapor pressures decrease. A fuel
with larger amounts of lower hydrocarbons will have a higher vapor
pressure and will evaporate faster. The lower boiling hydrocarbons
will tend to evaporate first, and the vapor pressure and the rate
of evaporation will then decrease.

All distillate fuels have at one time been evaporated during
the distillation process. The vapor pressures of all the components
are thus sufficiently high that essentially all spilled distillate
fuel that is not otherwise removed would eventually be lost by evapora-
tion. Residual fuels, such as NSFO, consist primarily of components
having negligible evaporation rates. Therefore, a comparatively small
amount of the NSFO would be lost by evaporation.

Thickness. The thickness of an oil slick is an important factor
in its evaporation rate because the evaporation takes place at the
surface of the film. At a given moment, the amount of oil evaporated
is not affected by the depth of the oil, and the percentage loss
is therefore much greater for a thin film with a high surface-to-volume
ratio. Over a period of time, the composition at the surface will change
to less volatile components and the more volatile components will migrate
to the surface from the interior of the oil layer. This process is more
rapid in a thinner layer or in agitated oil.

Temperature. The temperature will affect the evaporation rates
because it affects the vapor pressures of the components. The temperature
also affects the viscosity of the oil and the rate of migration of
the components. However, the range of ocean temperatures is limited,
and the effect of temperature is expected to be small compared to
the effect of differences in composition.

Wind. Wind will affect the evaporation rate because it provides
fresh air that is not already partly saturated by the components
of the oil. In a completely stagnant situation an equilibrium
would be created in which all components would be present in
the air in direct proportion to their vapor pressures, and any
net additional evaporation would cease. Rapidly moving fresh
air will prevent any approach to saturation and will have the
same net effect as an increase in vapor pressure.

Evaporative Losses

The experimental results were in agreement with the above
considerations. The evaporation experiments with thin films of
fuel oils show that under rapidly moving fresh air the major
portions of the distillate fuels will evaporate. About 95% or
more of the distillate fuels were lost in a week under these
conditions, whereas only 33% of the NSFO was lost, as shown in
Figure 5. However, the thickness of these fuel oil films was only O.1 mn,
and much lower evaporation rates would be expected for thicker films.

In the simulated weathering of Navy distillate fuels spilled on
seawater, the fuel losses in one week were from about 10% to about 25%.
The oil thickness in these experiments was 5 mm. The thickness of a
typical oil spill might be about half this thickness.

The thickness of an oil spill will vary, of course. In a
controlled spill of No. 2 fuel oil there was reported to be a
compact region of oil 2.4 + 0.3 mm thick, surrounded by a thin region
only 0.002 to 0.004 mm thick [5]. The thick region contained more than
90Z of the oil in less than 10% of the area of the visible slick.
According to the specifications, No. 2 fuel oil [6] is a slightly
lighter oil than Navy distillate fuel [3], but fuel oils A to D
exhibited properties very close to, or within the range, specified for
No. 2 fuel oil. Thus, the evaporation characteristics of a typical spill
of Navy distillate fuel are likely to be closer to those of a 5-mm
layer, which is about twice as thick, than to a 0.1-mm layer, which
is about one twentyfifth the thickness of the bulk of the reported spill.

One reason for using an oil thickness of 5 mm in the simulated
weathering was to have sufficient oil residues to study their
properties. A second reason for using a relatively thick layer
of oil was to have enough material to collect the bulk of the
weathered oil directly without a complicated recovery system.

In the weathering experiments with the distillate fuels it was
fortunately possible to recover most of the evaporated oil by
simply syphoning it off the top of the salt water. In the
collection of the remainder of the oils by extraction with

hexane and subsequent removal of the hexane (to determine the total
recovered oil) there were slight additional losses, but experiments
indicated that these losses were less than 1% of the extracted
portion of the weathered oils.

A method similar to that used in the present experiments had
been used by Smith and MacIntyre [2]. These authors had used one
tenth as much oil, twice as much salt water, and one third of the
airflow. They collected the volatile constituents that were carried off
in the airstream by condensing them in a cooled trap. The collected
volatile material was dissolved in pentane and subjected to gas
chromatography; and, from the area of the oil peaks of the gas
chromatogram, the weight of volatile material was calculated. Smith
and MacIntyre considered the volatiles to be those components boiling
at temperatures not higher than DUG, ene boiling point of pentadecane
(C15). They also sampled oils from controlled spills and from the peak
heights determined the losses of individual hydrocarbons. They found
that the losses in volatiles were much more rapid in oils spilled
at sea, especially when there was wind, and that the volatiles
lost at sea included much higher proportions of Cy, and C15 hydrocarbons.

In the present investigation, the weathering was increased by
adding the effect of wind produced with a paddle. The airflow was
increased also, but increased airflow alone would have much less
effect than the use of the paddle. Airflow introduced at the bottom
of the flask pushes aside the oil, and increased airflow produces
relatively little increased contact.

Gas chromatography is a commonly used technique in the study of
petroleum products, because it gives considerable information about the
composition of the relatively volatile components. The components come
off the colum in order of volatility or boiling points (as shown
in Figures 1 to 4), and the areas under the peaks are proportional to
the amounts of the various components. To a lesser degree, the peak
heights are also proportional to the amounts present. Both of these
relationships have been used for quantitative calculations. Thus,

Smith and MacIntyre have calculated the losses of specific hydrocarbons
from fuel oils [2], and Sivadier and Mikolaj have calculated the loss
of volatiles from crude oil slicks [7].

The data from the gas chromatography of the original and weathered
Navy distillate fuels was used to calculate the portion of oil remaining
after weathering. For these calculations, the components boiling below
298°C were considered to be volatile, and the components boiling above
298°C were considered to be nonvolatile. The calculated results for
1-week simulated weathering agree within 2% with the amounts of oil
that were recovered, as shown in Table 4. For the longer weathering of
Oil C, the deviation was greater.

The initial evaporative losses of spilled Navy distillate fuels can
thus be determined rather closely by a comparison of the gas chromatograms
of the original and weathered oils. The losses on more extended weather-
ing cannot be determined as accurately. Partly this is due to the fact
that there is no discrete demarcation between the ‘‘volatile’’ and
**nonvolatile’’ portions of the oils. Instead, there is a wide range of
volatility of the many components.

The significance of the gas chromatographic results and the calcu-
lations that were made are further discussed in the Appendix.

A comparison of the gas chromatograms with the thin film evaporation
experiments indicates that the weight loss in short term weathering is
greater for oils with a greater portion of low boiling components. On
the other hand the persistence of thin films is greater for oils with
a greater portion of high boiling components. Thus, Oil C evaporated
least rapidly in the simulated weathering experiments and in the beginning
of the thin film evaporations. However, the same oil evaporated most
rapidly at the end of the thin film evaporations; and, in that
sense, it was the least persistent of the oils.

All of the four Navy distillate fuels had distillation temperatures
considerably below the specification requirements. Thus, other Navy
distillate fuels could be within the specification but because of higher
distillation temperatures, they could be appreciably less volatile and
more persistent.

Dissolution and Dispersion

Fuel oils spilled at sea will also sustain losses due to dissolution
and dispersion; but, based on investigations reported in the literature, it
is expected that these losses ordinarily would be small and would not
appreciably reduce the bulk of the oil. There is a concern, however,
that significant amounts of toxic components might be disseminated in
the aquatic environment [8].

The solubility of hydrocarbons decreases with increasing molecular
weight [9]. It is comparatively low for aliphatic hydrocarbons, being less
than 1 ppm for normal octane. The solubility increases with increased
unsaturation and is considerably higher for aromatic compounds. The
solubility is about 50 ppm for isopropylbenzene, but it is lower for the
higher molecular weight aromatics present in fuel oils. The aromatic
components are not only more soluble than the aliphatic components,
but are also more toxic [8]. In one investigation, the seawater
extracts of kerosene and of a crude oil contained about 1 ppm aromatics [8].
In another investigation, a maximum of 13 ppm of organic material was
extracted from No. 2 fuel oil in a closed static system [10].

The dissolution of fuel oil at sea, in a dynamic system, is a
complicated problem beyond the scope of the present investigation.

A higher organic content of the seawater might be produced by the
presence of dispersed material, rather than dissolved material, which
may be difficult to distinguish. The small amounts of volatile compounds
originally dissolved might be removed comparatively rapidly by aeration.

10

Components of the oil that are dispersed into water will become more

volatile because their vapor pressure is effectively augmented by that of

the water, and a ‘‘steam distillation’’ will occur. Similarly, the presence

of water should effectively augment the vapor pressure of the bulk oil

and speed its evaporation, especially where there is a turbulent interface.
The salt water extracts from the simulated weathering experiments

contained 14.5 to 37 ppm of organic carbon, as shown in Table 6, and thus

about 17 to 44 ppm of organic compounds. These are higher concentrations

than expected on the basis of the literature quoted above, but lower

concentrations than obtained in two unpublished investigations. Because

the salt water extracts were very clear, it is doubtful that the increased

organic content was due to dispersed material. It is more likely that

the increased organic content was due to the presence of oxygenated

organic compounds that might have been formed by the aeration of the

fuel oils. The total dissolved organic compounds, extracted from the

330-ml portions of the oils by the 6-liter portions of salt water (a

ratio of 1:18), constituted 0.037% to 0.093% of the original oils.

These figures are very close to the 0.053% of dissolved oil that Smith and

MacIntyre found in their weathering of 30 ml of No. 2 fuel oil in contact

with 10 liters of salt water (a ratio of 1:333) [2].

Changes in Viscosity

The viscosity changes of the Navy distillate fuels in the
simulated weathering were not very great. The values in centistokes
increased by a maximum of 45%, as shown in Table 5. This change is
equivalent to the change obtained when the temperature of the oils is
lowered from about 22°C to 10°C (or from about 70°F to 50°F). This is
the temperature change that would give the same increases in viscosity
according to graphs on standard viscosity-temperature charts [11]. An
oil evaporated to the same extent at sea might pick up foreign matter,
and the viscosity might thus increase somewhat further.

Navy special fuel oil exposed to the same simulated weathering gave
very different results. These differences apparently were caused by the
greater viscosity of the NSFO, by its greater density, and probably by
the presence of more polar constituents. The agitation of the NSFO was
not as effective. A thick emulsion of NSFO and salt water was formed
which broke into clumps but did not form very small particles in the
salt water. When the aeration was stopped, this ‘‘mousse’’ formed a
layer about 30 mm thick and did not change in thickness for four days.
The distillate fuels, on the other hand, had separated and coalesced
rapidly.

The results with the NSFO are not as reliable as those with the
distillate fuels because of experimental difficulties. About half of
the evaporated NSFO was recovered by decanting and the remainder by
extraction with dichloromethane and subsequent evaporation. However,
there were unavoidable losses and the residue was probably greater than
the indicated 92%. The viscosities of the NSFO could be measured only

11

approximately with the available apparatus. Although the viscosity change
of about three-fold was larger than that of the distillate fuels, this
change again was equivalent to only a 12°C (or 20°F) temperature change
when plotted on a viscosity-temperature chart. However, this change
occurred with a smaller evaporation loss. Also, this was the viscosity

of the recovered NSFO, and the viscosity of the ‘‘mousse’? might have
been higher.

CONCLUS IONS

1. Navy distillate fuels are relatively persistent oils and do not
evaporate rapidly in thick films.

2. Initial weathering of thick films of spilled Navy distillate fuel
should not materially change the amount of oil that must be salvaged.

In simulated weathering of 5-mm fuel oil films on salt water for one week,
the Navy distillate fuels left residues of 75% to 90% of the original
oils.

3. Initial weathering of thick films of spilled Navy distillate fuel
should not materially change the handling characteristics of the oils.
Simulated weathering of 5-mm fuel oil films on salt water produced
small increases in viscosity and small changes in boiling range.

4. Very thin films of Navy distillate fuel will evaporate much more
rapidly than Navy special fuel oil. Navy distillate fuels exposed in
O0.1-mm films under a current of air for one week, left residues of
about 5%, whereas the Navy special fuel oil left a 65% residue.

5. The weathering characteristics of distillate fuels can be correlated
with their gas chromatographic behavior. Oils with greater portions of
low boiling components (below about C,5) will have higher initial losses,
and oils with greater portions of high boiling components (above about
C290) will leave greater residues.

6. In simulated laboratory weathering, the persistent emulsion formed
with Navy special fuel oil is not formed with Navy distillate fuel.
ACKNOWLEDGMENT

The assistance of Mr. C. W. Mathews in the experimental work is
appreciated.
REFERENCES

1. S. A. Berridge, R. H. Dean, R. G. Fallows, and A. Fish. ‘‘The
properties of persistent oils at sea,’’ in Scientific aspects of

it

pollution of the sea by oil, Journal of the Institute of Petroleum, London,
November 1968.

2. C. L. Smith and W. G. MacIntyre. ‘‘Initial aging of fuel films on
seawater,’’ in Proceedings of Joint Conference on Prevention and Control
of Oil Spills, Washington, D.C., 15-17 June 1971, pp. 457-461.

3. Military Specification MIL-F-24397 (ships): Fuel, Navy distillate.
2, Aoby WSNOe)e

4. R. E. Kreider. ‘‘Identification of oil leaks and spills,’’ in
Proceedings of Joint Conference on Prevention and Control of Oil Spills,
Washington, D. C., 15-17 June 1971, pp. 119-124.

5. J. P. Hollinger and R. A. Mennella. ‘‘Oil spills: measurements of
their distributions and volumes by multifrequency microwave radiometry, ’’
Science, vol. 181, 6 July 1973, pp. 54-55.

6. American Society for Testing Materials. Standard D 396-69: Standard
specification for fuel oils.

7. 4H. O. Sivadier and P. G. Mikolaj. ‘‘Measurement of evaporation rates
from oil slicks on the open sea,’’ in proceedings of Joint Conference on
Prevention and Control of Oil Spills, Washington, D.C., 13-15 March 1973,
pp. 475-484.

8. D. B. Boylan and B. W. Tripp. ‘‘Determination of hydrocarbons in
seawater extracts of crude oil and crude oil fractions,’’ Nature, vol.
230, 5 March 1971, pp, 44-47.

9. C. McAuliffe. ‘‘Solubility in water of paraffin, cycloparaffin, olefin,
acetylene, cycloolefin, and aromatic hydrocarbons,’’ Journal of Physical
Chemistry, vol. 70, April 1966, pp. 1267-1275.

10. J. W. Frankenfeld. ‘‘Factor governing the fate of oil at sea;
variations in the amounts and types of dissolved or dispersed materials
during the weathering process,’’ in Proceedings of Joint Conference on
Prevention and Control of Oil Spills, Washington, D. C., 13-15 March 1973,
pp. 485-495,

11. National Research Council. International critical tables, New York,
19275 WOlle ILS jo WAZ.

13

APPENDIX

DETERMINATION OF OIL EVAPORATION BY
GAS CHROMATOGRAPHY

Gas chromatography can be used to estimate the losses of volatile
components from fuel oils or crude oils. The following calculations
form the basis for the brief discussions in the body of the report.

If it is assumed, as a simplification, that a mass of oil, M, is
composed of a volatile portion, M,, and a ‘‘nonvolatile’’ portion, M,, then

Ms Be (1)

If the nonvolatile portion is sufficiently volatile to be gas-chromato-
graphed readily, and if the above masses are proportional by a factor, a,
to the respective areas, A, in the gas chromatogram of the original o0i1,°,
then

ie) fe) oO oO

Mo eee Novem aA =mahcertavc (2)
Vv nN V 10}

Because of the slightly different sample size and columm conditions, a
different factor, b, will apply to the gas chromatogram of the weathered
oul Weand

Mm” = MY + mM” = bA” = bAY + dA” (3)
V nh

If the nonvolatile portion does not change appreciably on weathering, then

MQ = MY, and since Mp = aAQ, and My = bAY,
aA® = bAY (4)
n n

and
A

=— (5)
A
n

The portion of oil, P, remaining on weathering is

W Ww
M bA
aS ao) (6)
M
and, substituting Equation 5 in Equation 6,
Mia
Dp SeS= 8 =| = (7)
Met yA AW
n

In the calculation of the portion of oil remaining after the
weathering of Navy distillate fuels by means of Equation 7, the volatile
portion was considered the portion boiling below 298°C and the nonvolatile
portion that boiling above 298°C. The results obtained are shown in Table
4. The calculated results were generally somewhat high. Because some of
the nonvolatile portion will nevertheless evaporate, it would be expected
that the values of AY would be somewhat low and that P would be somewhat
high. The results were especially high for the initial 6-week experiment
with Oil C, giving a value of 0.781 for the portion remaining, whereas
the recovery of the oil was 74.7%. In this longer evaporation, a higher
proportion of the nonvolatile hydrocarbons were probably lost.

For residual fuels or for crude oils, Equation 7 cannot be used,
because the higher boiling components are not completely recovered in
the gas chromatography. For the evaporation of crude oils, Sivadier
and Mikolaj therefore developed a more complicated equation which involves
the areas between the C17 and C2g hydrocarbon peaks, comprising components
boiling between 300°C and 431°C [7]. These ‘‘truncated residues’? are
assumed to be nonvolatile and their areas, Ary» are used analogously to
A, to establish the proportionality between the area factors, b/a, of the
gas chromatograms. Their equation for the weight fraction of oil evapora-
ted, F, also includes the portion of volatiles originally present in the
oil, Ore as determined by distillation up to 288°C:

ie) ie)
IN? fp

SQ (ts (8)
Ary! Ao

The evaporative weight losses calculated from the gas chromatographic
data and the losses obtained from direct weighing of oil samples evaporated
in dishes in the laboratory agreed within 17.

The above agreement was better than that obtained for the Navy
distillate fuels by use of Equation 7. This may be due partly to the fact
that the ‘‘truncated residuum’’ was much larger and of higher average

15

boiling point than the nonvolatile portion of the distillate fuels. It
may also be due partly to the fact that the percent losses from the crude
oils were generally much smaller than the percent losses from the distillate
fuels.

In a manner analogous to the derivation of Equation 7, it is possible
to derive the following equation for the portion retained, R, of any
particular hydrocarbon during the weathering:

fou Hw ae
IK 18

57 ae ao (9)

x x 18

Here C is the amount of a particular hydrocarbon present originally and
after weathering, and H is the peak height of that hydrocarbon and of
another hydrocarbon that is assumed to be nonvolatile. Octadecane (C18)

is the hydrocarbon that is assumed to have negligible volatility and the
ratio in parentheses is a measure of the ratio, b/a, between the overall

sensitivities of the two gas chromatograms. Actually, octadecane does

evaporate to some extent, and the calculated R is a comparative portion

retained as compared to the portion of octadecane retained.

The comparative retentions of the normal alkanes from dodecane (C49)
to heptadecane (C17) in the simulated weathering of Oils C and D are
shown in Figure 7. The effect of omitting the wind in the weathering of
Oil D and the effect of much longer weathering of Oil C are also shown.
The comparative retentions of the hydrocarbons decrease markedly as their
size and boiling points decrease. Furthermore, these differences in
retention are markedly increased for any particular oil as the degree of
weathering is increased.

The curves of the comparative retentions also show that appreciable
amounts of Cy@ and C;7 hydrocarbons are lost, as compared to C1g. With
increased weathering, it would be expected that increasing amounts of Cjg
and higher hydrocarbons would be lost and that increasingly higher
hydrocarbons would have to be used as reasonably valid internal standards
for gas chromatographic comparisons. For mild weathering, the approximation
that certain hydrocarbons are nonvolatile may give adequate mathematical
comparisons; but for severe weathering, the same approximation may not be
suitable. Because the distillate fuels in some cases have very small
amounts of components higher than Cig; they do not contain good internal
standards.

Smith and MacIntyre used an equation very similar to Equation 9 to
calculate the percentages of various normal hydrocarbons that remained
in oil spills after various periods of time, using the Cyg peak rather
than the C;g peak as a reference [2]. Qualitative trends were established
in the evaporation of the various hydrocarbons, but it was difficult to
ascertain accurate peak values. Calculations of the loss of volatiles
(up to C15) were also made, but there was no possibility of measuring
actual losses for comparison.

‘VV TEO Teng [TeuLsT1o0 Jo weaZ0j,ewoAYyoD sey

‘e| ein3Ty

Ost ool
(9) tut0d Butj108 T T | T T T j= r T T ir 1 T
vz zz oz al at bh ZL OL 8
en SS T T T T T T

=

—

ile

‘Vy TEO Tend perteyqeeM FO weiZojeworzys sey “q| eANnsTy

— (do) 3ul0g Bur!0g ~ T = 1 ae T oe t oe | oe 1 OD |
174 (aa 0z gL OL LAs (Aas oL 8
Ce aan a alee ane an aL T T T T T |

18

°g [TO Teng TeuTsTz0 jo weasojzeworyo sey

(00) tulod Buit08

a

swory uoqied

°eZ eANn3Ty

19

Or ose oe sz 00z OSL ol

(99) 4u!ed Bu ——- r 4 ———T t | 1 t r r
eatet 74 zz oz sl gt vl Zz ol 8

SS FRO oo T T T T T T T

‘g THEO Teng pezeyqeem Jo werzzo0jeUoIYS SeO

"qZ eansTa

\

20

“2 TEFO [Teng TeuTstz0 Jo weasojeworyds sey “ee oiNn3Ty

> (99) tl0d Burj!0g T T T T T T T T T T T T +

Se re) Teri sees pclae ees oe T T T T T T T T T T T T 1

21

°) ITO Teng pereyzeem Fo wearZojeMOIYD sep

"qe eansty

tye
vz zz 0z Bl 9L vl ZL ol 8
a SED) Soo see! T T i T T

22

‘ad IfO Teng TeUTSTIO Jo weazojeuoryD sey

‘ey eINn3Ty

00r ose ooe osc 00z ost ool
(9) Wwiog Burj1og T T T T T T T T T T T T T
174 (44 0z gL OL bl Zt OL 8
See OR) le Laon ee T T Tr T = T T T T T T = T T

23

°d Ito Teng porsyjeem JO weiZojzeUOrYD sey

0Ov

“qp eansTy

(0) uo BuI108 —— —

>———— sion uoquep ——

24

Amount Remaining (%)

Figure 5.

2 4 6 8
Exposure (days)

Evaporation of thin films of fuel oils.

(Oils A through E exposed in a stream of air.)

23)

Apparatus for simulated weathering.
26

Figure 6

Comparative Retention

Figure 7.

12 Ca, C16 Cig

Hydrocarbon

Comparative retention of-low boiling hydrocarbons.
(For Oils C and D weathered one week, Oil c”
weathered six weeks, and Oil D weathered without
wind.)

27

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