Introduction
Approximately 44,000 oil and gas
exploratory and development wells have been drilled in the US
Federal waters of the northern Gulf of Mexico since 1947 (Figure
1). These wells have encountered a variety of temperature
conditions that range from abnormally low to abnormally high,
indicating that the pattern of subsurface heat in the basin is
complex. Limited data has been published documenting temperatures in
specific wells, fields, or local areas, but the only regional
temperature analyses of the area are modeling studies that predict
timing of hydrocarbon 
maturation
by tracing temperature evolution
(Mello and Karner, 1996; Jones and Nagihara, 2003; Jones et al.,
2003). No studies exist that show the detailed regional distribution
of present-day temperatures. This study summarizes our work in
putting together a map illustrating subsurface thermal conditions in
the northern Gulf and presents preliminary interpretation of the
spatial temperature patterns. Ideally such an analysis would be
carried out using equilibrium bottom-hole temperatures (BHTs)
measured from each well during geophysical logging runs. BHTs are
sporadically recorded on the well log headers, but they have not
been digitized or summarized in a systematic manner that is publicly
available. In addition, very few, if any, wells have recorded the
data necessary to calculate equilibrium BHT values. Publicly
released wells are available through the Minerals Management Service
(MMS), but the number of logs exceeds 250,000 for the 44,000 wells
drilled. The time and expense necessary to purchase and process
these logs would be excessive. We therefore have relied on publicly
available data on average sand temperatures in fields calculated by
the Minerals Management Service supplemented by data from 90 wells.
The
result of our analysis is a map that illustrates below-mudline (BML)
depths to the 300-degree (BMLD300) subsurface isotherm throughout
the northern Gulf. This map can be considered as a portrayal of
subsurface temperature distribution, as the BMLD300 values are a
direct reflection of thermal gradient, thermal conductivity, and
heat flow. The map illustrates the complexity of subsurface
temperatures in the northern Gulf. In some cases this complexity can
be related to known geological conditions, but in other cases the
relationship is ambiguous. The most serious shortcomings of the map
are (1) its dependence on average values for calculating thermal
gradients, (2) a mixed source of original temperature values
(derived from both non-equilibrium BHT data measured during logging
runs and temperatures measured during bottom-hole pressure surveys)
and (3) the relative paucity of data in deep-water areas (>1,000 ft
of water depth). Despite these weaknesses we feel the map documents
valid regional variations in temperature distribution and provides a
good tool for estimating temperatures for drilling and for
basin-analysis work. The map will be improved over time as new and
more accurate data becomes available.
It is well established that temperatures
increase with depth in the Earth, indicating that heat is generated
at depth and transferred through rock and sediment layers to the
surface. This so-called terrestrial heat flow is described by the
following equation:
(1)
where:
Qz = Heat
flow per unit area in the vertical direction
l
=
Thermal conductivity
 |
=
Geothermal gradient
|
Blackwell and Richards (2004) present the
most recent interpretation of heat flow in the Gulf of Mexico as
part of their Geothermal Map of North America, but little data on
thermal conductivity is available for the region. The thermal
maturation modeling studies that have proliferated in recent years
require thermal conductivities over an entire stratigraphic section
as an input to calculate heat flow. For the most part these values
are estimated from wells logs or extrapolated from analogous
geological settings. Thermal conductivity values used in the studies
are rarely published as part of a basic documenting data set.
Since heat flow and thermal conductivity
data are rarely available for petroleum applications, bottom-hole
temperatures measured in boreholes are the principal basis for
calculating geothermal gradients. The basic equation for the
calculation, and the method utilized in this study, is as follows:
........
(2)
Problem of Mean Annual Surface
Temperature
In calculating geothermal gradient using
equation 2 a value of mean annual surface temperature is subtracted
from the measured BHT before being divided by the formation depth.
The mean annual surface temperature serves as an approximation of
temperature at the top of the rock-sediment column. For the Texas
Gulf Coast area an annual mean surface temperature of 68-70°F is
typically applied. Because of the intervening water column, the air
temperature in offshore areas does not truly reflect temperature at
the top of the rock-sediment column (i.e., the mudline) and,
therefore, may produce spurious results in geothermal gradient
calculations. This is especially true in deep-water areas, where the
mean air temperature at the water surface may be considerably higher
than the temperature at the seafloor, or mudline. For the present
study, we have used the mean annual temperature at the mudline as
the “surface temperature,” thus eliminating the misleading influence
of a water column that is not in thermal equilibrium with the
underlying rock-sediment section. This standard has also been
adopted recently by both API Subcommittee 10 for estimating
subsurface temperatures for cementing and API Subcommittee 13 for
estimating subsurface temperatures for calculating the true density
and viscosity properties of drilling fluids at actual well-bore
temperatures.
Good data is available for water
temperatures versus depth through the World Ocean Database (http://www.nodc.noaa.gov/OC5/SELECT/dbsearch/dbsearch.html).
This data consists of mean annual water temperature-depth profiles
gathered over many years from the world’s oceans by the US National
Ocean and Atmospheric Administration (NOAA). For the northern Gulf
of Mexico 3495 profiles containing over 70,000 data points were
obtained and used in this study. A plot of the data points is shown
in Figure 2. We have averaged the data
values for successive depth increments of 100 feet, and these
average values are plotted in Figure 3.
Below 3800-3900 feet the average annual water temperature falls
asymptotically to a constant value of around 40° F (4.4º C) that
prevails to abyssal depths.
The gradient calculated for each field or
well is based therefore on a mud-line temperature that reflects the
water depth at which the field or well occurs. The resulting BML
geothermal gradient is a better reflection of heat flow and thermal
conductivity in the field or well, without the misleading influence
of the water column with its reversed (temperature decreasing with
depth) and unrelated thermal gradient.
Calculating Geothermal Gradients and
BMLD300 Values
Two sources of data were used to derive
geothermal gradients from which the BMLD300 was calculated:
The main data source was the Minerals
Management Service’s 2001 publication “Atlas of Northern Gulf of
Mexico Gas and Oil Sands.” In that work the MMS calculated a series
of weighted reservoir parameters for sands in fields recognized as
of January 1999. The MMS defined a “sand” as all productive
formations in a field that are geologically correlative. Reservoir
characteristics for all sands were calculated, weighted according to
the relative importance of the reservoir in the field, and averaged.
A particular sand’s temperature may be derived from many wells in a
field or from only one well, if only one produces from the
formation. Depth values assigned to the temperatures are weighted
average sub-sea TVD values of the wells producing from the sand.
Average weighted values obviously do not
reflect all possible variation in temperatures in a field. However,
as discussed in an earlier section, obtaining a regional grid of
good static bottom-hole temperatures from wells is essentially
impossible in the Gulf. We recognize the weakness in the data, but
feel strongly that it still allows a valid regional overview of
temperature distribution. An obvious advantage of the MMS data set
is its large size (13,000 average sand temperatures from 1041
fields) and its good regional distribution. Locations of the fields
that were used are shown in Figure 4.
Since the data available from the MMS
Atlas publication covers only fields recognized up to January 1999,
it was necessary to add data from individual wells to give better
coverage to deep-water areas, which have a limited number of fields.
We reviewed 4500 logs from 250 deep-water wells in which the BML
total depth was at least 15,000 feet or greater. Only 90 wells were
found to have usable temperature data. The distribution of the wells
used is shown in Figure 4.
To calculate gradients, an Excel
spreadsheet was developed that contained all data points for each
field and well. The BML depth of each data point was calculated by
subtracting the water depth from the average depth of the sand or
the depth of the value in a well. The MMS data had already been
converted to a sub-sea true vertical depth. We corrected the well
data to TVD-SS using directional survey data from the log headers.
An Excel macro was developed to plot data points from each field on
a temperature- depth graph (Figures 5,
6 and 7, for
examples). Each plot was examined and a gradient line or series of
gradient lines was visually established and drawn through the
points. The average annual mud-line temperature developed from the
World Ocean Database was used as the shallowest point (‘annual mean
surface temperature’).
After establishing the gradient lines,
values were extracted from each plot to calculate a gradient and a
BMLD300 value (Figures 5,
6, and 7).
If a field demonstrated dogleg gradients (see next section for
discussion), the temperature of the deepest point above the deepest
dogleg was recorded, and the gradient of this last step was used to
calculate the depth to reach 300°F in the field or well.
Dogleg Thermal Gradients
A commonly observed phenomenon in the
Gulf Coast and Gulf of Mexico is that geothermal gradients have two
or more distinct linear segments, indicating that the gradient
varies in a step-like fashion with depth. These gradient variations
are often coincident, or near-coincident, with the top of
overpressure in the stratigraphic section (Jones, 1969, Leftwich,
1993) or with a change in average thermal conductivity of the
section (Blackwell and Steele, 1989). Hunt (1996) has referred to
these zones of variable gradient as “dogleg geothermal gradients.”
In this study multi-linear, or dogleg,
geothermal gradients have been observed throughout the northern
Gulf, but not in all fields and wells. In many fields the gradient
trend shows no obvious change in rate (Figure
5). This may reflect the true gradient situation in the field,
or the data may not extend deep enough to intersect an insulating or
conducting zone (Lewis and Rose, 1970), such as an overpressure zone
or zone of thermal conductivity change. The apparent non-occurrence
of insulating zones in many plots may reflect as well the fact that
geothermal gradients calculated in fields by the MMS are almost
exclusively derived from sand reservoirs. The plots contain little
or no temperature data from shales, which form the great bulk of the
Gulf of Mexico’s stratigraphic section and are commonly the
insulating zones.
Multiple doglegs are interpreted to occur
in many fields in the study (Figures 6
and 7). Though it was out of the scope
of the present work, we feel that mapping the distribution of dogleg
thermal gradient zones could be useful in determining regional
patterns of overpressure and thermal conductivity change.
Mapping BMLD300 Values
To map the BMLD300 values we used the
field outlines published by the MMS in the 2001 Atlas study. A
latitude-longitude centroid was calculated for each field and this
was the point used to map the BMLD300 value in the field. Values for
wells were plotted at the bottom-hole locations. Contouring was
carried out initially with the automated contouring package Surfer
8.0 (trademark of Golden Software, Inc., 809 14th Street, Golden, CO
80401), using the Kriging method with a very dense gridding
interval. Most of the fields in the Gulf of Mexico produce from
multiple sands, and in many cases not all the sands in a field are
stacked vertically; some sands may be located in a position
displaced from the main body of the field. Every sand in a field
was, therefore, assigned a centroid and the same BMLD300 value, so
that displaced sands would be mapped within the contour value of the
field. The results were good, but since each field area is
represented in the gridding process by a single point, the boundary
areas of some fields and sands are partially contained in adjacent
contours.
The completed Surfer map was converted to
an ESRI (Environmental Systems Research Institute, Inc., 380 New
York Street, Redlands, CA 92373) shapefile and loaded into ArcGIS
9.0 (trademark of ESRI). The contours were converted to closed
polygons, and extraneous lines were cleaned up for final map
presentation.
Distribution of Subsurface
Temperatures in the Gulf
Figure 8 is
the completed interpretation of BMLD300 values for the northern
Gulf. The most remarkable aspect of temperature distribution is the
distinct differentiation between shelf and deep-water areas. The
shallowest BMLD300 values, and thus the highest thermal gradients
and heat flow, occur on the Texas-Louisiana shelf, which is the area
above 300 m (984 feet or approximately 1000 feet) water depth. At
these water depths BMLD300 values range from 9700 feet to 45,000
feet, but these extremes are uncommon and restricted in occurrence;
by far the most common depth range is 15,000– 19,000 feet.
In the deep-water areas, below 300 m of
water, the BMLD300 values range from 11,000 to 45,000+ feet, with
most common range being from 21,000 to 37,000 feet. Further
differentiations can be made within the deep-water areas between
water depth-ranges of 300m-1000m and 1000m-2000m, but these
distinctions are very subjective. In the shallower of these two
ranges the BMLD300 values range from 11,000 to 45,000 feet, with the
most common depths being 21,000 to 31,000 feet. Between 1000m and
2000m the BMLD300 values are 13,000 to 45,000+, with the most common
values being from 21,000 to 37,000 feet.
The average geothermal gradient, and
therefore subsurface temperature, tends to be lower in the
deep-water areas than on the shelf. This point is illustrated in
Figure 9, which shows the range of
BMLD300 values and the midpoint depth of the most prevalent range of
BMLD300 for each protraction area in the northern Gulf (see
Table 1 for summary).
Though we feel that the general trend of
cooler temperatures in deep-water areas is real, it should be noted
that temperature patterns throughout the northern Gulf show a great
range of variability. There are areas on the shelf that are nearly
as cool as those in the deep- water, and areas in deep-water as warm
as those on the shelf.
Even a casual glance at
Figure 8 suggests that the area of the
study can be divided readily into distinct areas of temperature
distribution. We have interpreted six “temperature domains,” which
we define as regional geographic areas that share noticeable
similarities in their temperature distribution patterns, which can
be related to geological factors in the area (Figure
10).
This area, which includes the Texas shelf
and a portion of the western shelf of Louisiana, has the highest
temperature gradients and broadest pattern of shallow BMLD300 values
in the northern Gulf of Mexico. The shallowest BMLD300 value occurs
in the Brazos 437 (BA437) field at 9700 feet. The range of BMLD300
values in the domain is 9700 to 25,000 feet, but the dominant depths
range from 13,000 to 17,000 feet. Several temperature patterns that
can be directly related to geological features occur in the domain.
The northeast-trending BMLD300 contour pattern in the domain is
consistent with the known geology of the Texas offshore, which is
dominated by northeast-trending fault systems that extend for long
distances. The coincidence of the high temperature zone that falls
along the Corsair fault trend suggests a causative relationship (Figure
11). Bodner and Sharp (1988) found similar temperature highs
concentrated along the trends of the Wilcox and Vicksburg fault
systems, which parallel the Corsair and are located to the west of
it onshore south Texas. Perpendicular to the Corsair thermal high is
a northwest-trending high-temperature zone (shown by the
13,000-15,000-foot BMLD300 contour) that extends from the Brazos
area across Brazos South, Galveston South and into East Breaks. This
feature parallels the trend of the San Marcos arch, a basement nose
that plunges southeast from the Llano uplift.
Within the Texas shelf domain is another
anomalous area centered approximately in the High Island region.
This area is bounded to the northwest by the Corsair fault trend and
is the site of a late Miocene depocenter, as outlined by Winker
(1982). BMLD300 values in the domain range from 17,000 to 23,000
feet, classifying it as anomalously cool in relationship to the
surrounding Texas shelf domain. We speculate that a deep
overpressure zone or a shallow conductive zone may underlie the High
Island domain. Reference to Figure 1
shows that the High Island domain is also an area of remarkably
low-drilling density.
This area is characterized by BMLD300
values that range from 13,000 to 33,000 feet, with a most common
range of 15,000 to 19,000 feet. In addition to being generally
cooler than the Texas shelf domain the pattern of temperature
distribution is dominated by numerous small “bulls-eye” contour
anomalies, which contrast with the elongate pattern of contours on
the Texas shelf. This pattern is most likely a reflection of salt
dome tectonics that have produced the short, arcuate fault system
pattern that characterizes the Louisiana shelf. High temperature
anomalies are often associated with salt domes (Gretener, 1981). We
have compared the pattern of BMLD300 anomalies to the pattern of
known salt domes on the Louisiana shelf and find good general
agreement, though not absolute coincidence. In an investigation of
geothermal patterns around salt domes in south Louisiana, Kumar
(1989) found that there is a general rise in temperatures in the
vicinity of domes but that isotherms do not always conform to them.
This deep-water area coincides with the
Mississippi fan, a large complex that extends south from the edge of
the Louisiana shelf to abyssal depths and consists of a thick
section of Quaternary submarine deposits. BMLD300 values in the
domain range from 23,000 to 43,000 feet, with the most common depths
ranging from 27,000 to 37,000 feet. Mello and Karner (1996), Jones
and Nagihara (2003), and Jones et al. (2003) have suggested that the
rapid deposition of a thick section of young sediments in the fan
has suppressed regional isotherms, resulting in anomalously low
surface heat flow.
This deep-water domain coincides with the
Texas-Louisiana slope and is characterized by salt diapirism,
lateral emplacement of salt tongues and sheets, and from mass
downslope transport of surface sediments. Worrall and Snelson (1989)
have interpreted the Texas-Louisiana slope as a large overthrust
complex in which salt forms the basal thrust surface and in which
salt is tectonically thickened relative to the shelf areas. BMLD300
values range from 25,000 to 56,000 feet, with the most common values
in the range of 29,000 to 43,000 feet. It is tempting to relate the
deep BMLD300 values in some way to the dominance of salt-related
phenomena in the domain, but Jones et al. (2003) have concluded that
lateral salt tongues, such as those that characterize the
Texas-Louisiana Slope, do not affect heat flow. There is no evidence
in the domain of the rapid thick sedimentation that has formed the
Mississippi fan to the east. The low geothermal gradients in the
area are indeed anomalous, and we cannot relate them at the present
time to any known geological features. It should be noted however
that data control in the area is sparse and that interpretation of
thermal conditions in the area will no doubt become clearer with
additional data points.
This deep-water area displays BMLD300
values that are intermediate between those of the Texas Shelf and
Walker Ridge domains. The values range from 13,000 to 27,000 feet,
with predominant values from 21,000 to 25,000 feet. The area of the
Alaminos Canyon domain falls within two geological provinces
described by Ewing (1991), the Northwest slope diapir province and
the Perdido diapir province. The Northwest slope province has less
salt-tectonic activity and a thinner stratigraphic section compared
to the adjacent Texas Louisiana Slope. Though the Perdido province
displays considerable salt tectonic activity, the salt is fairly
continuous compared to the Texas-Lousiana slope to the east and the
stratigraphic section is thinner, not displaying the massive, rapid
sedimentation seen to the east. Like the Walker Ridge domain, the
Alaminos Canyon area suffers from sparse data, and its
interpretation will most likely change with additional control.
Equilibrium bottom-hole temperature data
in the northern Gulf of Mexico is difficult to obtain, but the use
of the large set of field-based sand data from the MMS supplemented
by wells gives a valid regional picture of thermal trends in the
basin. The interpreted pattern of BMLD300 (below-mudline depth to
300oF) values derived from geothermal gradients allows us
to divide the northern Gulf into six temperature domains. Three
domains on the shallow-water shelf areas have generally higher
geothermal gradients and shallower BMLD300 values than those in the
three deep-water domains. The shallowest BMLD300 values (and thus
highest heat flow values) occur in the Texas shelf domain and appear
to be related to the northeast-trending Corsair fault and possibly
the extension of the San Marcos arch. The deepest BMLD300 values
(and therefore the lowest heat flow values) occur in the Walker
Ridge and Mississippi fan domains. The Mississippi fan pattern can
be explained by rapid, thick sedimentation that has suppressed
regional isotherms resulting in low surface heat flow. The pattern
in the Walker Ridge area is more anomalous and cannot be related at
the present time to known geological features. Data control in the
deep-water areas is sparse, and the interpreted temperature trends
there are subject to significant future revision as additional
control becomes available.
Despite its data weaknesses the BMLD300
map gives a good preliminary overview of thermal conditions in the
northern Gulf and can be used readily by drilling engineers and
basin modelers as an indication of present-day subsurface
temperature distribution.
The authors gratefully acknowledge the
Synthetic-Based Mud Research Group for financial support of this
project and for their permission, with that of the American
Petroleum Institute, to publish this paper.
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