|
tIntroduction
tFigure
captions
t Basement
mapping
tAnticlinal
oil fields
tStratigraphic
traps
sOolitic
shoals
sAlgal
mound
sOffshore
bars
sFluvial
systems
sShoreline
bars
sFracture
production
tOther
techniques
tFinal
statement
tReferences
tIntroduction
tFigure
captions
tBasement
mapping
tAnticlinal
oil fields
tStratigraphic
traps
sOolitic
shoals
sAlgal
mound
sOffshore
bars
sFluvial
systems
sShoreline
bars
sFracture
production
tOther
techniques
tFinal
statement
tReferences
tIntroduction
tFigure
captions
tBasement
mapping
tAnticlinal
oil fields
tStratigraphic
traps
sOolitic
shoals
sAlgal
mound
sOffshore
bars
sFluvial
systems
sShoreline
bars
sFracture
production
tOther
techniques
tFinal
statement
tReferences
tIntroduction
tFigure
captions
tBasement
mapping
tAnticlinal
oil fields
tStratigraphic
traps
sOolitic
shoals
sAlgal
mound
sOffshore
bars
sFluvial
systems
sShoreline
bars
sFracture
production
tOther
techniques
tFinal
statement
tReferences
tIntroduction
tFigure
captions
tBasement
mapping
tAnticlinal
oil fields
tStratigraphic
traps
sOolitic
shoals
sAlgal
mound
sOffshore
bars
sFluvial
systems
sShoreline
bars
sFracture
production
tOther
techniques
tFinal
statement
tReferences
tIntroduction
tFigure
captions
tBasement
mapping
tAnticlinal
oil fields
tStratigraphic
traps
sOolitic
shoals
sAlgal
mound
sOffshore
bars
sFluvial
systems
sShoreline
bars
sFracture
production
tOther
techniques
tFinal
statement
tReferences
tIntroduction
tFigure
captions
tBasement
mapping
tAnticlinal
oil fields
tStratigraphic
traps
sOolitic
shoals
sAlgal
mound
sOffshore
bars
sFluvial
systems
sShoreline
bars
sFracture
production
tOther
techniques
tFinal
statement
tReferences
|
 Figure
1. Landsat image of fractured and lineated outcrops of the Canadian
Shield (yellow NW portion of image) and the onlap of lower Paleozoic
rocks of the eastern Ontario - western Quebec Basin (red south and east
parts of image) (from Lowman et al., 1992). City of Montreal, right
center; St. Lawrence River runs from lower left center to northeast
corner. The lineated basement terrane is not visible beneath the cover
rocks but is mappable with properly processed and interpreted
magnetic data.
 Figure
3. Example of basement mapping in Major and Woodward counties, Oklahoma,
on north shelf of Anadarko Basin.
Depth to basement - approximately 12,000 ft. (3,600m) beneath flight
level.
 Figure
4. Ponca City Field, Kay County, Oklahoma. This asymmetric, or
compressional, anticline has produced >12 million barrels of oil from
multiple horizons. Shear zone mapped by magnetics (blue) lies west of
the steep part of the fold mapped on the "Mississippi Lime" (red),
indicating a west dip for the underlying blind reverse fault (inset).
The west dip on this fault is also shown on seismic data.
 Figure
6. Collier Flats Field, Comanche County, Kansas.
Production is from an oolite shoal that evidently developed on a fault scarp over an
underlying basement fault defined by the gradient in the residual
magnetic contours (blue). Structure contours (red) are on top of
Pennsylvanian Swope limestone. (Slamal, 1985).
 Figure
7: Bug Field, Paradox Basin, San Juan County, Utah, showing correlation
between a producing Pennsylvanian algal mound and a basement block
boundary. Red contour lines are Pennsylvanian Desert Creek structure;
blue lines are profile residual magnetic contours at 0.5 nT interval.
The basement block corresponding to the magnetic high ("H") would have
tilted to the south with its north edge (red) upthrown, localizing the
algal mound. Structure contours from Krivanek (1981).
 Figure
8. Hartzog Draw Field (Powder River Basin), Campbell County, Wyoming.
A
one-on-one relationship exists between basement faults mapped by magnetics (blue) and late Cretaceous Shannon sand buildup (red).
 Figure
10. Echo Springs - Standard Draw - Coal Gulch Field, Sweetwater Country,
Wyoming, in the Washakie Basin, > 1 tcf of gas.
This Upper Cretaceous
Almond sand bar, as defined by net sand isopach map (red) has been
identified as a shoreline bar. It follows precisely along a basement
fault interpreted from magnetic contours (blue) and is probably
controlled by it (John Horne, personal communication, 1998).
Movement on
the fault was perhaps only a few tens of feet, and was therefore not
imaged by a 3-D seismic survey run on the north part of the field
(beneath limit of seismic resolution).
Return
to top.
Examples of Basement
Structure
Figure 1 is a Landsat photograph that
covers a portion of the Canadian Shield (NW part) and a portion of the
adjacent Ontario sedimentary basin (SE part), where the shield is
overlapped by oil-bearing lower Paleozoic strata.
The highly fractured nature of basement
in outcrop is obvious, but the sedimentary rocks in the basin hide this
fracture pattern from view. The basement fractures are reactivated at
later times during, or after, deposition of the sedimentary section and
create structures and/or sedimentary facies that become oil and gas
traps and reservoirs. Thus, the mapping of the fracture pattern under the
sedimentary section is of great importance in hydrocarbon exploration.
How can this best be accomplished?
Neither seismic nor gravity methods can map the basement fracture
pattern, although both can map part of it. Subsurface data cannot map
the basement in any detail due to the limited number of basement
intercepts in most basins. Only magnetics can map the covered basement
fault block pattern. Why can magnetics do this? It is because of the rock
type changes (resulting in magnetic susceptibility changes) that occur
across the basement faults.
Figure 2
is a detailed surface geology map of a 30 x 30 mile (50 x 50 km) block
of basement on outcrop in Wisconsin. The basement faults (actually shear
zones) are shown, and the rock type changes across them are obvious.
Shear zones in the basement are one, two, or three kilometers in width,
are characterized by crushed and broken rock across the entire width,
and are usually steeply dipping. It is these pre-existing zones of
weakness that relieve stresses resulting from later tectonic events
and/or sedimentary loading. Stresses are not generally relieved by newly
formed faults at ±30° to maximum compressive stress, at least not in the
last two billion years. Other characteristics of importance:
-
The distance between shear zones is
usually two, three, or four miles (3-7 kilometers),
-
They fall into sets of parallel
structures,
-
Three or four different sets of shear
zones may occur.
The resulting melange of basement blocks
is called the "basement fault block pattern. "
How does one go about mapping the
basement fault block pattern with magnetics?
Figure 3a shows a total
intensity aeromagnetic survey on the north flank of the Anadarko Basin,
Oklahoma, flown with one-mile spaced east-west flight lines. The
sedimentary section is 10,000-12,000 feet thick; the aircraft was
approximately 1,000 feet above mean terrain. This map is dominated by a
single magnetic high on the west and an elongated low on the east, 16
miles away. It obviously is not mapping the blocks. To bring out the
individual blocks it is necessary to residualize the data or to
calculate second derivatives. Either will suffice, although some
computational techniques are better than others (I prefer profile
residuals calculated along flight lines where possible, as shown in
Figure 3b).
Each of the magnetic highs and lows
represents a separate basement block, and the faults (shear zones) occur
on the intervening boundaries, or gradients. These faults have been
marked with shear zone symbols (red) in Figure 3c; the fault block
pattern by itself appears in Figure 3d (blue). A detailed subsurface map
of this area yielded only two faults cutting the sedimentary section
(shown in red in Figure 3d). They occur precisely along or very close to
the mapped basement faults as hypothesized. This is but one example of
the correlation of basement shear zones with mapped faults. Since 1982 we
have generated hundreds of such cases of correlating faults. Also shown
in red in Figure 3d is a structural high mapped using subsurface data at
West Campbell Oil Field that falls between basement shear zones. As
basement shear zones generally erode “low,” we hypothesize that the West
Campbell high is coincident with a basement topographic high and was
formed by differential compaction. Compaction anticlines represent
another type of basement control important in exploration.
Figure 3 is useful in demonstrating
another point: Both subsurface faults shown have magnetic lows on their upthrown sides. If structure were the only factor in determining
magnetic amplitudes, magnetic highs would occur on the upthrown sides.
However, the lithology of the basement is the primary influence on
magnetic maps, and structure is a secondary, and sometimes
insignificant, factor.
Anticlinal Oil
Fields Over Basement Faults
Figure 4 shows the relationship of an
asymmetric fold (Ponca City field, Kay County, Oklahoma, with production
to 1993 > 12 million barrels) to an underlying basement fault, shown
with shear zone symbols. Pennsylvanian compression reactivated the
fault, forcing the west side up along a west-dipping fault to give rise
to the overlying fold in Paleozoic strata (see lower part of
Figure 4).
The fault is "blind", as it does not
break through to the level of the folded strata.
Figure 5
shows a fault that has broken
through to the level of the folded strata in Sage Creek anticline in the
Wind River Basin, Wyoming, resulting in a thrust-fold structure. The
location of the thrust at basement level is shown by shear zone symbols.
This is but one of a chain of several folds in the western Wind River
Basin that correlates closely with mapped basement faults. It has a
strike length of 70 miles and involves seven separate faults. Four
faults are northwest-trending, parallel to the Casper Arch thrust; three
are cross-faults that successively offset the northwest-trending faults
to the north.
We have developed over two dozen
examples of asymmetric folds related to basement faults such as those
shown in Figures 4 and
5. The cause and effect relationship can be
clearly seen. The conclusion is apparent that pre-existing basement
faults are reactivated to give rise to the fold-forming faults in the
overlying sedimentary section. As noted above, the best (and only) way
to map the basement fault pattern in sedimentary basins is with properly
processed and interpreted aeromagnetic data.
Return
to top.
I shall try to substantiate the claim
that many--and possibly a majority--of oil and gas fields are controlled
by basement, with examples of several different types of "purely"
stratigraphic traps related to basement faults. Some geologists may
concede that the evidence for underlying basement control is convincing.
Others will not. I argue that, if a basement fault is in exactly the right
location and has exactly the right strike direction relative to a
stratigraphic feature of interest, it probably is not coincidental. It
must be cause and effect.
Oolite Shoal
Over Basement Fault
Figure 6 shows the location of a
southwest Kansas oil field in Pennsylvanian oolitic limestones. The
oolite bank was deposited on the probable upthrown side of an underlying
basement fault. A nearby fault mapped from seismic data is also shown in
red, as are the structural contours on top of the Pennsylvanian
limestone.
Pennsylvanian Algal Mound Over Basement
Fault
Figure 7 shows the relationship of a
Pennsylvanian algal mound field in Utah to an underlying basement fault.
Uplift of the north edge of the tilted basement block under the field could
have raised the sea floor to a shallow water environment, allowing the
development of the algal mound.
Offshore Bars
Over Basement Faults
Figure 8 shows the relationship of Hartzog Draw Field (that has produced approximately 220 million barrels
of oil) in the Powder River Basin, Wyoming, to an interpreted underlying
basement fault. Swift and Rice (1984) proposed that the sandstone
reservoir in this field and other similar fields in the basin were
formed by the winnowing action of bottom currents over sea floor highs.
The sea floor high could have resulted from the raising of a basement
block edge during late Cretaceous (Laramide) compression.
Other nearby fields showing similar
one-to-one relationships to magnetically mapped basement faults are:
-
Dead Horse-Barber Creek
-
Nipple Butte-Holler Draw
-
Culp-Heldt Draw
-
Poison Draw
-
Scott
-
House Creek
Figure 9 shows the prolific Fiddler
Creek Field (in the Powder River Basin), which produces from a lower
Cretaceous fluvial sand in the Muddy Formation, as it relates to an
underlying interpreted basement fault. Fracturing and jointing along
this fault zone would have made the underlying rocks more susceptible to
erosion, creating a topographic low along which the river flowed and
deposited sands.
We have located four other such
correlations of fields in the Muddy Formation in this basin with
underlying basement faults:
Of related interest, several of the
present-day drainages in the basin, such as the Belle Fourche and Little
Powder Rivers, follow precisely along basement faults for long
stretches.
Figure 10 shows the prolific Echo
Springs - Standard Draw - Coal Gulch Late Cretaceous shoreline bar (>l tcf of gas) in Wyoming's Washakie Basin, and its relationship to an
interpreted basement fault. Because of the manner in which the sands are
stacked, an up-to-the-west fault on the west side of the field is
expected (John Horne, personal communication, 1998). It is precisely
here that a magnetically mapped basement fault is located. The throw on
this fault is minimal, perhaps a few tens of feet, as suggested by
comparison to faults controlling deposition in the similar Cardium
Formation in the Western Alberta Basin (e.g., Hart and Plint, 1993).
This small amount of throw was below the limit of resolution of a 3-D
seismic survey carried out over the field's northern part in 1996-97 (Favret
and Clawson, 1997).
Fracture Production
As noted above, the creation of fracture
reservoirs is closely related to fault control, but in fracture plays
the amount of vertical fault movement can be minimal. We have documented
a number of cases where fracture production is coincident with mapped
basement faults.
In southern Ohio in the Appalachian
Basin, for example, a 250% increase in the average gas production in a
Clinton-Medina well resulted from drilling on a magnetically defined
fracture intersection.
Our most compelling fracture correlation
has been in the Bakken play of North Dakota, where we obtained
production data on 158 horizontal wells and used a computer program to
calculate all EUR's in similar fashion. This database was compared to
locations of magnetically defined basement faults. Wells drilled in
corridors 1.5 miles (2.4 km) wide centered on basement faults yielded 21
percent higher EUR's than those drilled farther away. In the southeast
quadrant of the play this figure was 41 percent higher.
Many of these wells were drilled
parallel or subparallel to basement faults, and at the edges of the
corridors. We believe the production figures would have been higher if
the wells had been drilled with a knowledge of the locations and strike
of the basement faults beforehand. Why? Because eight wells drilled
within a 0.75-mile radius of basement fault intersections yielded EUR's
85 percent higher than wells away from intersections.
Return
to top.
Comments On Other Magnetic Mapping Techniques
How do the above processing and
interpretational techniques for basement compare to the new "HRAM"
methods? "HRAM" stands for "high resolution aeromagnetics," a technique
that employs very tight flight line spacing (100-500m) flown at low
flight levels (50-150m) and generally displayed as color-coded shade
relief maps of total intensity.
It is claimed that HRAM can map the
traces of faults within the sedimentary section due to magnetite formed
along the faults and can locate areas of higher surface diagenetic
magnetite content related to micro-seepage. Both of these claims are
speculative and controversial. It is also claimed that HRAM can locate
pipelines and other cultural features; this is true, but these have
questionable value in exploration. For basement mapping there is no
technical or computational advantage for the tight flight line spacings
and low level flying employed by HRAM.
The foregoing examples and figures
should demonstrate to exploration managers that the magnetic method,
properly applied, is an indispensable tool in almost any exploration
program. Magnetics, however, has not been generally used to map basement
faults. Instead, the technique has been applied mainly to peripheral
problems of lesser importance, such as depth estimation. With the
increasing effectiveness of 3-D seismic, magnetics has thus fallen
behind in use.
Bird, D., 2001, Interpreting magnetic data, Search and Discovery Article
#40022.
Clark, S.K., and J.I. Daniels, 1929, Relation between
structure and production in the Mervine, Ponca, Blackwell, and South
Blackwell oil fields, Kay Cunty, Oklahoma, in Structure of
typical American oil fields, v. 1: AAPG special publications, p.
158-175.
Favret, P., and S. Clawson, 1997, 3-D reservoir
characterization with horizon visualization and coherency/inversion
animations, GGRB, Wyoming (abstract): AAPG Bulletin, v. 81, p. 131.
Hart, B.S., and A.G. Plint, 1993, Tectonic influence on
deposition and erosion in a ramp setting: Upper Cretaceous Cardium
Formation, Alberta Foreland Basin: AAPG Bulletin, v.77, p. 2092-2107.
Krivanek, C.M., 1981, Bug field, T36S-R25E and R26E, San
Juan County, Utah, in Geology of the Paradox basin: RMAG, p.
1-21.
LaBerge, G.L.1981, Marathon County area, in 1981
Archean geochemistry field conference; Upper Peninsular and northern
Wisconsin, IGCP, Archean Geochemistry Project, U.S. Working Group,
United States.
Lowman, P.D., Jr., P.J. Whiting, N.M. Short, A.M. Lohmann,
and G. Lee, 1992, Fracture patterns on the Canadian Shield; a lineament
study with Landsat and orbital radar imagery, in Basement
tectonics, v. 1: Proceedings of the Seventh International Conference, p.
139-159.
Slamal, B. 1985, Collier Flats field, Comanche County,
Kansas, in P.M. Gerlach and T. Hansen, eds., Kansas oil and gas fields,
v. 5: Kansas Geological Society, p. 43-52.
Swift, D.J.P.,
and D.D. Rice, 1984, Sand bodies on muddy shelves--a model for
sedimentation in the Western Interior seaway, North America, in
C.T. Siemers and R.W. Tillman, eds., Ancient shelf sediments: SEPM
Special Publication No. 34, p. 43-65.
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