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uAbstract
uFigure
captions
uIntroduction
uArea/methods
uStratigraphy
uResults
uConclusions
uAcknowledgments
uReferences
uAbstract
uFigure
captions
uIntroduction
uArea/methods
uStratigraphy
uResults
uConclusions
uAcknowledgments
uReferences
uAbstract
uFigure
captions
uIntroduction
uArea/methods
uStratigraphy
uResults
uConclusions
uAcknowledgments
uReferences
uAbstract
uFigure
captions
uIntroduction
uArea/methods
uStratigraphy
uResults
uConclusions
uAcknowledgments
uReferences
uAbstract
uFigure
captions
uIntroduction
uArea/methods
uStratigraphy
uResults
uConclusions
uAcknowledgments
uReferences
uAbstract
uFigure
captions
uIntroduction
uArea/methods
uStratigraphy
uResults
uConclusions
uAcknowledgments
uReferences
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Figure and Table Captions
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Figure 1. Location of study area
and physiographic map of the Permian Basin. Garza County is
located on the central Eastern Shelf of the Midland Basin. Happy
Spraberry  field (star) is located in south-central Garza County.
Modified from Handford, 1981. |
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Figure 2. Lott 19 #4 well log
with core photographs and photomicrographs of reservoir interval
at Happy Spraberry field. The productive interval (A) consists
of oolitic grainstones and packstones with well-developed skel-
and oomoldic porosity which approach 1 cm. B is lithoclastic
rudstone with in situ Tubiphytes bindstone in the right
portion of the core photograph. Large bryozoan fragments and
replacive anhydrite are visible in the photomicrograph. C is a
quartz siltstone with primary intergranular porosity. D is
matrix-dominated lithoclastic floatstone with large, complete
fossils present. Scalebar: Core photographs = 1 cm,
photomicrographs = 100 mµ. |
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Figure 3. Histogram of pore data
from sample Lott 19 #4, 4944.9’. A photomicrograph of the sample
is located at top right. Scalebar = 100 mµ. Size is plotted on
the x-axis, frequency on the y-axis, and shape per pore bin is
also shown. Pore type is denoted by abbreviation; M = moldic, IM
= incomplete moldic, and SEIG = solution enhanced intergranular.
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Table 1. Summation of pore data
obtained from PIA. The four pore facies served as the
classification system for reservoir quality. Shown are pore
size, shape, origin, frequency, and expected porosity and
permeability values for each facies. Data were used to construct
flow unit stratigraphy based on pore measurements from PIA. |
Return to top.
This study tests the applicability of PIA as a tool for identifying
reservoir flow units in the carbonate reservoir at Happy Spraberry
field. The reservoir interval is interpreted to be lower Leonardian in
age and part of the Lower Clear Fork Formation, which is shelf
equivalent of the Dean Formation (Handford, 1981; Mazzullo and Reid,
1989). The depositional model for Happy field, interpreted by Hammel
(1996) and Roy (1998), is an oolitic grainstone shoal complex with
floatstone and rudstone debris aprons around patches of in situ
Tubiphytes bindstone buildups. Their interpretation is supported by
core descriptions, thin-section examination, and wireline log analyses
done in this study.
Happy field is located in south central Garza County, Texas, on the
eastern shelf that flanks the Midland Basin (Figure
1). Data used in the study include core from five wells, 52
petrographic thin-sections, capillary pressure measurements, and
wireline log data. Cores were described for sedimentary structures,
constituent grains, and depositional fabric (Layman II, 2002).
Thin-sections were examined by standard petrographic methods for total
porosity, per abundance, pore types, grain constituents, and cements.
Wireline logs were used to calculate porosity on reservoir intervals
where core analyses were absent. Cross plot porosity from CNL-FDC logs,
general log signature, as well as pore facies information were used to
correlate subdivisions of the reservoir zones across the field.
Petrographic image analysis of carbonate pores has been used to predict
reservoir quality (Anselmetti, 1998; Ehrlich, 1987; Ehrlich et al.,
1991). In this study, pore geometry was measured using PIA, and the
resulting measurements were related to reservoir quality. Petrographic
image analysis was performed on the thin-section data set using Image
Pro Plus, an image acquisition and analysis software program. Images
from thin-sections were captured by a Sony DXC-290 digital video camera
that relayed the signal to a PC. Ten images per thin-section were viewed
at 12.5X magnification and analyzed with the software. Porosity was
identified and measured for pore size, shape, frequency, abundance, and
pore origin. Pores were auto-classified by the software according to
geometry, and measurement data were plotted into histograms. These
“porosity fingerprints” have implications as to reservoir quality and
petrophysical characteristics. This method allowed for a much faster and
cheaper alternative to reservoir quality assessment and flow unit
mapping based on pore data obtained from PIA.
The carbonate interval at Happy field is interpreted as Lower Clear Fork
Formation (lower Leonardian). This is time-equivalent to the basinal
Dean sandstone (Montgomery, 1998). Primary production is from a
grainstone shoal complex with associated lithofacies (Figure
2). The shoal is composed of well sorted, medium-grained oolitic
grainstones and packstones; the interval averages about 20 feet in
thickness. Lithoclastic rudstones and floatstones containing fragmented
and whole mollusks, crinoids, and fenestrate bryozoans are common as
fringe deposits around the small skeletal buildups. The buildups are
composed mainly of encrusting organisms and Tubiphytes-rich
bindstone that grew mainly in the central part of the field between two
larger grainstone bodies (Ahr and Hammel, 1999).
The types of data obtained from PIA studies include pore size, shape,
frequency, and abundance (total porosity). In addition, pores in each
sample were classified according to their geological origin. Total
porosity from PIA was compared to porosity values obtained from standard
petrographic methods, log calculations, and core analyses. The
comparisons showed that the accuracy of PIA estimates of porosity are
comparable to the other methods. Porosity histograms were constructed
from the pore data to assess all pore characteristics rapidly (Figure
3). Samples were then correlated to determine trends and patterns in
the pore data that defined pore facies of the reservoir.
Pore facies are combinations of pore data that have predictable
reservoir potential and petrophysical characteristics. Four pore facies
were identified in the reservoir and associated carbonate section at
Happy Spraberry field. These pore facies serve as the basis for the
quality classification scheme. The highest quality or “best” pore facies
occurs in the oolitic/skeletal grainstones that typically exhibit 15-25%
porosity and 12-25 millidarcies (md) of permeability. This pore facies
consists mainly of moldic and solution-enhanced intergranular pores that
were produced by diagenetic leaching of grains and interstitial cement.
Intermediate quality pore facies typically exhibits 15-25% porosity and
5-12 md permeability. Rock types consist of moderately cemented skeletal
grainstones and packstones in which the dominant pore types are
incomplete moldic and solution-enhanced intergranular. The pore facies
with the lowest reservoir quality is composed of two subfacies. The
higher quality subfacies includes isolated molds in highly cemented
oolitic skeletal grainstones where leaching only affected metastable
grains. Other scattered grains underwent micritization, stabilization,
and neomorphism. As a result, pores are commonly isolated, disconnected,
and may be classified as separate vugs (Lucia, 1983). Porosity
histograms of this pore facies typically show the influence of large
(greater than 10,000 mµ2), separate molds, and less than 20%
of any other pore type or size. Porosity averages 10-14%, but it may be
as high as 25%. Permeability is typically less than 5 md. Overall the
lowest quality pore facies is present in silty, skeletal packstones,
siliciclastic siltstones, and rudstones. Typically, porosity is less
than 10%, and permeability is less than 10 md. This rock type has
abundant quartz silt that is locally more porous and permeable than its
surrounding carbonate rocks. Large, blocky vugs are also typical in this
pore facies. Table 1 is a summary and
ranking of the pore facies and associated pore data of each one.
Conclusions
Happy Spraberry field produces from heterogeneous, shallow-shelf
carbonates where lateral and vertical variations in porosity and
permeability are common. Porosity is predominantly a diagenetic
overprint on depositional texture (grain-moldic in oolitic grainstones).
Utilizing PIA as a method for characterizing carbonate reservoirs is a
relatively new procedure. Data on pore characteristics is obtained much
faster than standard petrographic methods.
Image analysis data were interpreted to identify 4 distinctive pore
facies which, in turn, are predictors of rock type, petrophysical
properties, and production characteristics. Image analysis was proven to
be a good substitute for more time-consuming methods for determining
porosity and provided results with accuracy comparable to results
obtained from core analyses, wireline log calculations, and standard
petrographic methods. The highest quality reservoir rocks occur in
oolitic grainstones and packstone where large (greater than 10,000 mµ2)
moldic pores dominate. Also, the highest combined values of porosity and
permeability were associated with the presence of large,
solution-enhanced intergranular pores in addition to the moldic pores (oomoldic
and skelmoldic). We interpret that storage capacity existed in the
moldic pores and that solution-enhanced porosity provided connectivity.
Pore size data obtained from petrographic image analysis is a useful
predictor of median pore throat size, which would otherwise only be
available by performing expensive mercury injection capillary pressure
tests. The list to avoid pitfalls of petrographic image analysis
includes choosing a magnification that gives appropriate and accurate
images of porosity, quality control on preparation of thin-section
samples, and consistent sampling of thin-sections.
This study was part of a Master’s Thesis at Texas A&M University. I
would like to thank the members of my committee: Wayne Ahr, Tom
Blasingame, and Steve Dorobek. I would also like to thank Bob Berg for
substituting at my defense. I would also like to thank those who funded
this research: AAPG Grant-in-Aid, Texas A&M University Graduate
Fellowship, and the late Mr. Michel T. Halbouty for a generous
scholarship.
Ahr, W.M. and B.S. Hammel, 1999, Identification and
mapping of flow units in carbonate reservoirs: An example from the Happy
Spraberry (Permian) Field, Garza County, Texas USA: Energy Exploration &
Exploitation, v. 17, p. 311-334.
Anselmetti, F.S., S. Luthi, and G.P. Eberli, 1998,
Quantitative characterization of carbonate pore systems by digital image
analysis: AAPG Bulletin, v. 82, p. 1815-1836.
Ehrlich, R., S.J. Crabtree, K.O. Horkowitz, and J.P.
Horkowitz, 1991, Petrography and reservoir petrophysics I: Objective
classification of reservoir porosity: AAPG Bulletin, v. 75, p.
1547-1562.
Ehrlich, R., and J.P. Horkowitz, 1987, Estimation of
petrophysics from thin-section; petrographic image analysis, in
AAPG 1987 Southwest Section meeting abstracts: AAPG Bulletin, p. 238.
Hammel, B.S., 1996, High resolution reservoir
characterization of the Permian (upper Leonardian) Spraberry Formation,
Happy Spraberry Field, Garza County, Texas: Unpublished Master’s Thesis,
Texas A&M University, 1996, 157 p.
Handford, C.R., 1981, Sedimentology and genetic
stratigraphy of Dean and Spraberry formations (Permian), Midland Basin,
Texas: AAPG Bulletin, v. 65, p. 1602-1616.
Layman II, J.M. 2002, Porosity characterization utilizing
petrographic image analysis: Implication for rapid identification and
ranking of reservoir flow units, Happy Spraberry field, Garza County,
Texas: Unpublished Master’s Thesis, Texas A&M University, 2002, 112 p.
Lucia, F.J., 1983, Petrophysical parameters estimated
from visual description of carbonate rocks: a field classification of
carbonate pore space: Journal of Petroleum Technology, v. 35, p.
626-637.
Mazzullo, S.J. and A.M. Reid, 1989, Lower Permian
platform and basin depositional systems, northern Midland Basin, TX,
in P.D. Crevello, J.L. Wilson, J.F. Sarg, J.F. Read, eds., Controls
on carbonate platform and basin development: SEPM Special Publication
no. 44, p. 305-320.
Montgomery, S.L., and W.H. Dixon, 1998, New depositional
model improves outlook for Clear Fork infill drilling: Oil & Gas
Journal, v. 96, p. 94-98.
Roy, E., 1998,
High resolution mapping of flow units for enhanced recovery program
planning, Happy Spraberry Lime Field , Garza County, Texas: Unpublished
Master’s Thesis, Texas A&M University, 1998, 106 p.
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