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Permeability Heterogeneity in Bioturbated
Strata, Cardium Formation, Pembina Field, and
the Identification of Potential Waterflood
Opportunities
by
Oliver J. Friesen
B.Sc. (Hons.) University of British Columbia 2013
Thesis Submitted in Partial Fulfillment of the
Requirements for the Degree of
Master of Science
in the
Department of Earth Sciences
Faculty of Science
Oliver J. Friesen 2015
SIMON FRASER UNIVERSITY
Summer 2015
ii
Approval
Name: Oliver J. Friesen
Degree: Master of Science (Earth Sciences)
Title: Permeability Heterogeneity in Bioturbated Strata, Cardium Formation, Pembina Field, and the Identification of Potential Waterflood Opportunities
Examining Committee: Chair: Dr. Dirk Kirste, Associate Professor
Dr. Shahin Dashtgard Senior Supervisor Associate Professor
Dr. James A. MacEachern Supervisor Professor
Dr. Dale Leckie External Examiner Adjunct Professor Department of Geoscience University of Calgary
Date Defended/Approved: July 23, 2015
iii
Abstract
Bioturbated sediments representing distal expressions of paralic depositional
environments are increasingly being exploited for hydrocarbons in the super-giant
Pembina Field (Cardium Formation), Alberta, Canada. These strata were previously
considered unproductive due to limited vertical and horizontal connectivity between
permeable beds. In these “tight oil” plays (0.1 – 10 md), pressure decay profile
permeametry data indicate that sand-filled burrows provide vertical permeable pathways
between bioturbated and parallel laminated sandstone beds in the central, north-east and
north-west parts of the field. This relationship enables the economic exploitation of
hydrocarbons via horizontal drilling and multi-stage hydraulic fracturing. As the exploitation
of bioturbated strata progresses in the Pembina Field, additional primary targets are being
sought out, and horizontal waterflooding is being considered in areas where current
horizontal wells exist. Proximal to historical produced conventional targets, reservoir
analyses indicate that areas where the bioturbated facies average permeability lies
between 0.35 mD and 0.85 mD and sandstone isopach thicknesses are between 0.25 m
and 2.5 m should be targeted in east-central Pembina.
iv
Acknowledgements
Firstly I would like to thank Dr. Shahin Dashtgard for allowing me to take on this project
and for his guidance and mentorship throughout the entire process. I would also like to
extend a sincere thank you to Dr. James MacEachern for also providing me with
mentorship and feedback throughout the process.
Many thanks to my fellow SFU colleagues, and specifically those in the ARISE group
including Andrew LaCroix, Korhan Aryanci, Kristyn Smith, Sean Borchert, Amy Hsieh, and
Macy Jones who all helped me along during the process.
I would also like to thank all of those at ARC Resources Ltd. who allowed me to undertake
this project, and provided me with feedback and invaluable mentorship during this
process.
Finally I would like to thank the SFU Earth Sciences department support staff including
Matt Plotnikoff, Rodney Arnold, Glenda Pauls and Tarja Vaisanen who were always
available to help when I needed it.
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Table of Contents
Approval .......................................................................................................................... ii Abstract .......................................................................................................................... iii Acknowledgements ........................................................................................................ iv Table of Contents ............................................................................................................ v List of Tables ................................................................................................................. vii List of Figures................................................................................................................ viii
Chapter 1. Introduction ............................................................................................. 1 1.1. Research Objectives .............................................................................................. 2 1.2. Methods ................................................................................................................. 3 1.3. Study Area .............................................................................................................. 5 1.4. Cardium Stratigraphy .............................................................................................. 7 1.5. History of Ideas..................................................................................................... 15
1.5.1. Turbidity and Storm Rip-Currents ............................................................ 15 1.5.2. Offshore Terrace Bars ............................................................................. 16 1.5.3. Stranded Shoreface Deposits .................................................................. 16
Chapter 2. ...................................................................................................................18 2.1. Facies Descriptions .............................................................................................. 18
2.1.1. Facies 1 (F1): Silty mudstone to shale with very fine-grained sand laminae .................................................................................................... 20
2.1.2. Facies 2 (F2): Bioturbated sandy mudstone to muddy sandstone with thin sandstone beds ......................................................................... 22
2.1.3. Facies 3 (F3): Massive to bioturbated sandstone with thin mudstone and siltstone beds ................................................................... 29
2.1.4. Facies 4 (F4): Unbioturbated, massive- to hummocky cross-stratified sandstone ................................................................................. 32
2.1.5. Facies 5 (F5): Clast- and matrix-supported conglomerate ....................... 35 2.2. Facies Associations .............................................................................................. 38
2.2.1. Facies Association One (FA1): Sandying-upwards shelf/ramp to upper delta front (middle shoreface equivalent) deposits ......................... 38
2.2.2. Facies Association Two (FA2): Conglomeratic Transgressive Deposits .................................................................................................. 39
2.3. Cardium Type Logs .............................................................................................. 39
Chapter 3. Permeability Heterogeneity in Bioturbated Strata, Cardium Formation, Pembina Field, and the Identification of Potential Waterflood Opportunities1 .................................................................... 43
3.1. Introduction ........................................................................................................... 43 3.1.1. Stratigraphy and Paleogeography ........................................................... 44 3.1.2. Study Area and Pembina Development History ....................................... 47
3.2. Methods ............................................................................................................... 49 3.2.1. Pressure Decay Profile Permeameter (PDPK) Analyses ......................... 50
vi
3.2.2. Permeability Calculations ........................................................................ 50 3.2.3. Contouring (using Golden Software Surfer®) ........................................... 52
3.3. Results ................................................................................................................. 52 3.3.1. Facies ...................................................................................................... 52 3.3.2. Facies Association One (FA1): Sandying upwards shelf/ramp to
upper delta front (middle shoreface equivalent) deposits ......................... 57 3.3.3. Facies Association Two (FA2): Transgressive Conglomerate
Deposits .................................................................................................. 57 3.3.4. PDPK ...................................................................................................... 60 3.3.5. Reservoir Characterization ...................................................................... 62 3.3.6. Mapping .................................................................................................. 63
3.4. Reservoir Controls on Production ......................................................................... 69 3.4.1. PDPK ...................................................................................................... 69 3.4.2. Sandstone Isopach .................................................................................. 69 3.4.3. Bioturbated Facies Kgeometric ..................................................................... 70
3.5. Waterflooding and future exploitation potential in east-central Pembina ............... 73 3.6. Conclusions .......................................................................................................... 76
Chapter 4. Conclusions ........................................................................................... 77 4.1. References ........................................................................................................... 80
Appendices ...................................................................................................................88 Appendix A: AppleCore Well Logs ......................................................................... 89 Appendix B: Well Compilation Data ..................................................................... 128 Appendix C: PDPK Analysis Data ........................................................................ 139 Appendix D: Horizontal Well Data ........................................................................ 162
vii
List of Tables
Table 2.1: Facies summary ..................................................................................... 19
Table 3.1: Facies summary ..................................................................................... 55
viii
List of Figures
Figure 1.1: Cardium Formation section ...................................................................... 5
Figure 1.2: Study area map ........................................................................................ 6
Figure 1.3: Cardium fm stratigraphy ........................................................................... 8
Figure 1.4: Stott (1963) stratigraphic chart ............................................................... 10
Figure 1.5: Cardium Formation Allostratigraphy ....................................................... 12
Figure 1.6: Evolution of the E5 surface .................................................................... 14
Figure 1.7: Carrot Creek conglomerate depositional model ...................................... 17
Figure 2.1: Examples of F1 ...................................................................................... 21
Figure 2.2: Examples of F2a .................................................................................... 23
Figure 2.3: Examples of F2b .................................................................................... 25
Figure 2.4: Examples of F2c .................................................................................... 27
Figure 2.5: Examples of F3 ...................................................................................... 32
Figure 2.6: Examples of F4 ...................................................................................... 34
Figure 2.7: Examples of F5 ...................................................................................... 38
Figure 2.8: Core litholog 03-07-048-08W5 ............................................................... 40
Figure 2.9: Core litholog 10-17-049-06W5 ............................................................... 42
Figure 2.10: Cardium type log legend ........................................................................ 42
Figure 3.1: Cardium Lithostratigraphy ...................................................................... 45
Figure 3.2: Paleogeography ..................................................................................... 47
Figure 3.3: Study Area ............................................................................................. 48
Figure 3.4: Facies core images ................................................................................ 56
Figure 3.5: Core litholog 03-07-048-08W5 ............................................................... 59
Figure 3.6: Cardium type log legend ........................................................................ 60
Figure 3.7: PDPK measurement positions (03-07-048-08W5 & 08-11-049-05W5) .................................................................................................... 61
Figure 3.8: PDPK versus facies plots ....................................................................... 62
Figure 3.9: Sandstone (F3, F4) sandstone isopach map .......................................... 64
Figure 3.10: Bioturbated facies (F2b, c) permeability map ......................................... 66
Figure 3.11: Bioturbated facies (F2b, c) isopach thickness map ................................. 68
Figure 3.12: Bioturbated facies (F2b, c) versus monthly oil production (horizontal wells) .................................................................................... 72
Figure 3.13: Bioturbated facies permeability versus production bar graph.................. 73
ix
Figure 3.14: Final waterflood map .............................................................................. 75
1
Chapter 1. Introduction
The Cardium Formation of the Western Canada Sedimentary Basin (WCSB)
comprises a terrigenous clastic wedge deposited along the western margin of the Western
Interior Seaway during the Late Turonian and Coniacian (Krause et al., 1994; Plint et al.,
1986; Walker, 1983b). The Cardium Formation has been studied for over 50 years since
the discovery of significant hydrocarbon reserves, presently estimated to be approximately
10.6 billion barrels of oil originally in place (ERCB, June 2011). While many conventional
oil pools in the Cardium Formation are past their peak production, the improvements in
multi-stage fracturing techniques has led to the discovery of an additional 1 billion barrels
of potential reserves, located mainly in the oil-charged halo of existing pools (Fig. 1; ; New
Technology Magazine, 2011). Water flooding through horizontal wellbores is an enhance
oil recovery (EOR) scheme that is presently being evaluated in the Pembina Field. This
study provides an in depth analysis of permeability heterogeneities of the bioturbated
facies in the central Pembina Field, with the intention of establishing how bioturbated
reservoirs in the Cardium Formation might respond to waterflooding.
The Cardium Formation records a complex depositional history involving tectonic
and eustatically controlled changes in sea level that led to the formation of multiple
allostratigraphic surfaces (Krause et al., 1994). Deposits of the Cardium Formation are
mainly mudstone, sandstone, and conglomerate deposited in and along eastward
prograding shoreline-to-shelf clinoforms (Krause et al., 1994).
Early exploitation of the Pembina Field targeted high permeability shallow-marine
sandstones and foreshore conglomerates through more than 4300 vertical wells (Nielsen,
1957; Parsons, 1955; Parsons and Nielsen, 1954). These wells were drilled between 1953
and 1980, and enhanced oil recovery schemes, including water flooding and infill drilling
were implemented shortly after. In fact, in Canada the first use of EOR, horizontal wells,
2
and hydrocarbon-based miscible floods were undertaken in 1957 in the Cardium
Formation, Pembina Field (Clarkson and Pedersen, 2011; Howes, 1988). Recent
advancements in horizontal drilling and multistage hydraulic fracturing have led to a
resurgence of interest in the Cardium Formation. New horizontal wells target the “halo” of
the main Pembina Field (Clarkson and Pedersen, 2011), and many have proven to be
successful. Three-month initial production (IP3) values for new horizontals are as high as
30,000 bbl oil (e.g., 13-21-050-06W5). Conversely, some wells have yielded disappointing
results indicating that the controls on productivity within the “halo” are poorly understood.
An in-depth analysis of permeability heterogeneities within the target area, including the
evaluation of plug and whole core porosity/permeability data and high resolution pressure
decay profile permeametry (PDPK) measurements can allow for better prediction of well
performance. This analysis can also help predict how the bioturbated facies will respond
to horizontal waterflooding schemes at Pembina, where a recent pilot program resulted in
increased reservoir pressure and improved sweep efficiency (M. Tuhin, personal
communication, August 18th, 2014). The goal of this study is to use detailed core logging,
core-permeability measurements, PDPK permeability, and production data to evaluate
areas in east-central Pembina that comprise thick successions of bioturbated muddy
sandstones that would respond favorably to horizontal waterflooding or should be targeted
for additional horizontal well development.
1.1. Research Objectives
The purpose of the research explained in this thesis is to answer the following
questions and / or complete the following tasks:
1. Can bioturbated muddy sandstones and sandy mudstones be waterflooded
effectively? Rank the best areas of east-central Pembina for waterflooding through
horizontal wells.
2. What is the correlation between facies distributions, permeability-porosity
characteristics of facies, and production?
3. Is there a correlation between plug and full diameter permeability data and PDPK
results?
3
1.2. Methods
Thirty-eight cores through the Cardium Formation at east-central Pembina were
logged as part of this study (Appendix A). Cardium deposits were subdivided into informal
flow units, based on the total overall visual sandstone/siltstone percentage (including all
discrete beds, burrows, and interstitial grains). The stratigraphic interval of interest
encompass the bioturbated sandy mudstones to muddy sandstones, with overall
combined sandstone/siltstone content ranging from 30% to 80% (L. Schmitt, personal
communication, May 12th, 2014). This range was determined to contain the economically
exploitable resources across Arc Resources Ltd.’s land base in east-central Pembina.
An additional 171 wells with geophysical well logs and porosity/permeability data
were also selected from east-central Pembina to provide data to correlate cored intervals
across the field (based on gamma ray cut off values), and to construct
porosity/permeability and net-pay maps. The most recently drilled wells were selected
preferentially, with preference given to wells with available gamma ray, resistivity, and
neutron and density porosity log profiles. Selected wells also needed to have core-analysis
data for reservoir intervals below the 30% combined sandstone/siltstone content in order
to provide a consistent spread of data throughout the entire section of interest. The
positions of core analyses measurements was determined by comparing depth of
measurements to gamma curves and to nearby wells that have logged core. Once the 171
additional wells were selected, the core analysis data were compiled (Appendix B). Data
pulled from AccuMap included the samples’ upper and lower depths, upper and lower
formation depths, sample thicknesses, Kmax values and porosity values.
Of the 38 Cardium Formation cores, 11 wells were selected for Pressure Decay
Profile Permeameter (PDPK) analysis (Appendix C). When selecting core for PDPK
analysis, preference was given to: 1) cores that preserve the greatest thickness of section
between the upper Cardium Formation marker to the underlying Blackstone Formation
(Fig. 1.1), with preference given to cores that penetrate the unconventional bioturbated
sandy mudstones; 2) cores that have good quality well-log data, core analyses, and
4
production information; 3) cores that are equally spaced across the study area; and, 4) the
best quality cores that are at least 7.5 cm in diameter. From the 11 wells, 44 samples
were taken (4 samples taken from each well). Sample lengths ranged from 6–25 cm. From
the 44 samples, permeability measurements were taken from 11 to 23 points per sample
(dependent on the lithological heterogeneities within the samples and sample length) for
a total of 758 points. Sample locations from each slab were carefully chosen to ensure
measurements were taken across the range of lithologies in the sample, including
sandstone/siltstone filled burrows and laminae/beds, and mudstone/siltstone matrix.
5
Figure 1.1: Cardium Formation section
Core log position and associated gamma-ray log for the Cardium Formation (00/03-07-048-08W5). Cores that preserved the thickest section from underlying Blackstone Formation to upper Cardium reflector were selected. Blackstone and Cardium formation picks from AccuMap.
Samples selected for micropermeability measurements were slabbed and
micropermeability measurements were performed at Corelab in Calgary, Alberta, using a
PDPK-400. Cut samples were lightly sandblasted to ensure a good seal between the
slabbed surface and the O-ring attached to the PDPK-400 probe tip (0.4 cm diameter).
Following sandblasting, samples were cleaned with a toluene solution to chemically
remove any mobile hydrocarbons, and then placed in an oven to allow the sample to dry
fully. After drying the samples, permeability measurements were acquired. For each
measurement a good seal between the O-ring and the rock was required, and this was
ensured using acetone. With an air-tight seal established, gas was allowed to flow from
the PDPK-400 into the core at a 70 kPa initial upstream flow pressure. The decay of the
initial pressure was measured against time, and the collected data were corrected for
Klinkenberg-slippage effects. This accounts for the fact that gas molecules injected into
the sample move through the pore throat center and edge at the same speed (whereas in
liquids do not). Correction of the data yields Klinkenberg-corrected, liquid-equivalent
permeabilities measured in microdarcies.
1.3. Study Area
This research project focuses on the Cardium Formation within the east-central
Pembina Field (Township 47–50; Range 4–9W5) of Alberta (Fig. 1.2). The study area
covers a total area of 1500 km2 and the majority of the land base is presently either wholly
or partially owned by Arc Resources Ltd. As of October 2014, 2527 vertical wells and 374
horizontal wells had been drilled across the study area. The vertical and horizontal wells
have an abundance of core, core analyses, and production data, which were imperative
for the undertaking this study.
6
Figure 1.2: Study area map
Maps showing: (A) the location of the Pembina Field on a paleogeography map of the Cardium Formation in Alberta, Canada (after Krause et al., 1994): (B) the location of the study area within the Pembina Field; and (C) the location of logged cores (yellow stars) and logged cores which were also analyzed for micropermeability measurements (green stars).
7
1.4. Cardium Stratigraphy
The Upper Cretaceous Cardium Formation grades upwards from marine shales of
the Blackstone Formation, and passes upwards gradually into marine shales of the
overlying Wapiabi Formation (Fig 1.3; Krause et al., 1994). Outcrops of the Cardium
Formation have been studied in the north and south-central mountains and foothills of
Alberta, wherein the progradational edge of the Musreau and Kawka members are
exposed (Duke, 1985; Plint et al., 1988). In the subsurface, the Cardium Formation
extends below much of western Alberta, and as far south as the Sweetgrass Arch in
northern Montana, USA (Cobban et al., 1959). The Cardium Formation is part of the up to
1200 m thick Colorado Group, which is a regionally extensive succession consisting
predominantly of shale that extends across the WCSB (Bloch et al., 1993). The Colorado
Group is a dominantly eastward-tapering marine shale package that contains at least three
sandstone-dominated units: the Basal Colorado, Viking Formation, and Cardium
Formation (Bloch et al., 1993).
8
Figure 1.3: Cardium fm stratigraphy
Chronostratigraphic and lithostratigraphic breakdown of the Central Plains of Alberta from the Lower to Upper Cretaceous (144–66.4 Ma). The Cardium Formation (red rectangle on diagram) is part of the Colorado Group and overlies the Blackstone Formation and underlies the Wapiabi Formation. (ERCB, 2013)
9
One of the earliest lithostratigraphic frameworks for the Cardium Formation was
proposed by Stott (1963). Stott defined six members named the Ram, Kiska, Cardinal,
Leyland, Sturrock and Moosehound (Fig. 1.4). These members encompass either major
coarsening-upward successions separated by erosional surfaces (Ram, Kiska, Cardinal,
Leyland, Sturrock members), or continental deposits (Moosehound Member) visible in
outcrops in the Rocky Mountain Foothills (Stott, 1963). The Cardium Formation
lithostratigraphic nomenclature was re-evaluated multiple times since Stott’s (1963) work,
and many studies proposed formal divisions developed for specific Cardium fields. For
example, formal names for stratigraphic intervals in the Cardium Formation were proposed
by Walker (1983b, c) for Garrington-Caroline-Ricinus, by Krause and Nelson (1984) for
Pembina, and by Walker (1985) for Ricinus. Krause and Nelson (1984) attempted to
simplify the Pembina Field terminology by proposing that the Cardium Formation be
broken into two lithostratigraphic units representing the reservoir and overlying seal,
termed the Pembina River Member and Cardium Zone Member, respectively. Plint et al.
(1986) pointed out that Krause and Nelson’s (1984) member terminology did not follow
the standards of the North American Commission on Stratigraphic Nomenclature
(NACSN), which does not allow the same name to be used for the formation and member
(Cardium Formation & Cardium Zone Member); consequently, the names proposed by
Krause and Nelson (1984) were abandoned.
10
Figure 1.4: Stott (1963) stratigraphic chart
Stratigraphic chart showing the original terminology proposed by Stott (1963) developed from outcrop studies in the Rocky Mountain Foothills. The Moosehound Member represents the continental equivalents of the marginal-marine Leyland, Cardinal, and Kiska members.
One shortfall of the early stratigraphic terminology was the assumption that
mudstone, sandstone, and conglomeratic intervals within the Cardium Formation were
directly correlative as member boundaries – therefore resembling a layer cake geometry
(Plint et al., 1986). Duke’s (1985) outcrop study was the first to recognize that such a layer-
cake stratigraphy was not accurate, recognizing multiple intertonguing marine and non-
marine sequences that make up the Cardium Formation. The Plint et al (1986) proposed
stratigraphic framework was built on the outcrop work done by Duke (1985) and included
detailed subsurface analysis utilizing over 800 cores and 3000 well logs (Fig. 1.5). The
resulting allostratigraphic framework showcased the complexity of the Cardium Formation
11
and resulted in the definition of formal members separated by falling stage/lowstand
erosional (E) and transgressive erosive (T) surfaces. In total, seven falling stage/lowstand
(E1–E7) and transgressive erosive surfaces were identified (TI–T7; Fig. 1.5). These
surfaces were interpreted to be regionally extensive, and therefore represented
chronostratigraphic surfaces. Each falling stage/lowstand erosional surface was paired
with a corresponding transgressive surface, as erosion was controlled by allogenic
changes in sea level. Within this allostratigraphic framework, Plint et al. (1986) and Plint
and Walker (1987) broke the Cardium Formation into twelve members that represented
coarsening-upward sequences. Included in this framework were the Burnstick and Raven
River members proposed by Walker (1983c). The 12 members represent deposition in
three unique sedimentary environments. The conglomeratic sequences were interpreted
to have been deposited as roughly shoreline parallel bodies within lowstand or falling
stage shorelines, and the coarsening-upward mudstone to sandstone sequences were
deposited within a laterally prograding shoreface, or vertically aggrading shelf (Plint et al.,
1986; Wadsworth and Walker, 1991; Walker and Eyles, 1991). Another change to the
Cardium Formation stratigraphic framework proposed by Plint et al. (1986) was moving
the base of the Cardium Formation to the E1 surface, such that the upper portion of the
Blackstone Formation be included in the Cardium fm, as the stratigraphic equivalent of the
Kawka Member.
12
Figure 1.5: Cardium Formation Allostratigraphy
Proposed allostratigraphic framework for the Cardium Formation proposed by Plint et al. (1986) which is based on outcrop work by Duke (1985). Diagram shows bounding falling stage/lowstand erosional (E) and transgressive erosive (T) surfaces (amalgamated surface where E and T intersect). The red rectangle marks the stratigraphic interval investigated herein. The member names in capital letters are those used for this study and proposed by Plint et al. (1986), and the member names in lower case letters were proposed by Krause & Nelson (1984).
13
The most well studied falling stage/lowstand erosional surface, first introduced by
Plint et al. (1986), is the E5 surface. The E5 surface incised into the thickest succession
of shallow marine sandstones within the Pembina Field (Bergman and Walker, 1988;
Leggitt et al., 1990; Wadsworth and Walker, 1991; Walker and Eyles, 1991). Based on the
apparent absence of the P. novimexicanus Ammonite zone across the E5 surface, the
vertical transition from shallow marine sandstones into conglomerates is interpreted to
represent missing time caused by subaerial exposure and transgression (Braunberger and
Hall, 2001a, b; Hall et al., 1994; Krause et al., 1994; Walker and Eyles, 1991). A series of
sub-parallel, NW-SE trending erosional troughs with as much as 20 m of relief were
created during lowstand and transgression of the E5–T5 amalgamated surface (Fig. 1.6;
Bergman and Walker, 1988; Leggitt et al., 1990; Wadsworth and Walker, 1991; Walker
and Eyles, 1991). The erosional topography with multiple highs and lows is interpreted to
have been incised during step-wise marine transgression, and hence the orientation of
paleo-shoreline is parallel to the depositional axis of conglomeratic deposits within the
Cardium Formation (Bergman and Walker, 1988; Leggitt et al., 1990; Walker and Eyles,
1991). Owing to the clarity that Plint et al. (1986)’s allostratigraphic framework brought to
the Cardium Formation, most subsequent workers have adopted it. Additional surfaces
were later identified including the E6.5 surface by Walker & Eyles (1988), and the E5.2
and E5.5 surfaces by Shank (2012) which onlap north-westward onto the E5 surface.
14
Figure 1.6: Evolution of the E5 surface
Sequential depositional diagram showing the proposed formation and preservation of steps present along the E5 surface. A) Normal marine deposition ranging from offshore mudstones to shallow marine sandstones. B) Shoreline regression partially controlled by SE tectonic uplift, creating sanding upward sequences and eventually causing subaeriel exposure of previously inundated paralic deposits. In this paper it was argued that transgression eroded the evidence of continental deposits, which could have been created during subaerial exposure. C) Subsequent step-wise marine transgression leading to shoreline-parallel steps being cut via wave ravinement which controlled the distribution of coarse clastics above the E5 surface (from Leggit and Walker (1990).
15
1.5. History of Ideas
The depositional history of the Cardium Formation, particularly its oil-bearing
sandstones and conglomerates, has been debated for more than 50 years (Beach, 1955;
DeWiel, 1956; Plint and Walker, 1987; Plint et al., 1986; Walker, 1983a, c). There are
three main hypotheses for the origin and depositional history of Cardium Formation
sandstones and conglomerates.
1.5.1. Turbidity and Storm Rip-Currents
Beach (1955) proposed a turbidity-current source for the coarse clastics (sand and
gravel) of the Cardium Formation. His theory was based on the fact that the extreme lateral
continuity of the coarse clastics within an offshore position was inconsistent with pelagic
sedimentation. Beach (1955) believed that the coarse sands to pebbles were delivered to
an offshore position by gravity driven turbidity currents. This idea was expanded upon by
Walker (1983a, c), who drew on observations of the unit’s sedimentary structures to
support an argument for turbidity currents within the Western Interior Seaway at the time
of Cardium deposition. His evidence included the sharp erosional bases of the
conglomerates, which he claimed displayed vertical transitions from upper flow regime
(e.g. parallel-lamination) to lower flow regime bedforms (e.g. ripple cross laminations)
which are consistent with waning energy conditions in turbidity flows (Walker, 1983c).
Wright and Walker (1981) took a numerical approach to explain the emplacement
of sands and gravels several kilometers from the paleo-coastline. Based on their results,
they proposed a model involving basin-oriented storm-induced rip-currents. The Wright
and Walker (1981) argument hinged on the observation of hummocky cross-stratified
(HCS) sandstones in the Cardium Formation, which they believed were created by the
same long-period storm-generated density currents that transported the sediments below
fair-weather wave base. By assuming a 1.60 m/s bedload transport of sand and gravel by
offshore-directed storm-generated rip currents, it was concluded that it would take roughly
200 days of consistent storm conditions to emplace 1 cm diameter gravels into a position
16 km offshore (Wright and Walker, 1981). These calculations were ultimately used to
16
support the turbidity current model, as sand and gravel could be transported to the same
deposition site in only 3.9 hours if entrained in a high-density turbidity current (Walker,
1983c).
1.5.2. Offshore Terrace Bars
A second depositional model for the Cardium Formation, first proposed by Swagor
(1976) and later supported by Griffith (1982) and Nielsen and Porter (1984), interpreted
the sandstones and conglomerates of the Cardium as offshore terrace bars. Swagor’s
(1976) main argument supporting offshore terrace bars was the orientation of the
conglomeratic deposits, which in most areas are parallel or sub-parallel to the inferred
paleo-shoreline. This orientation was believed to be inconsistent with an offshore-directed
delivery mechanism such as tidal, fluvial or turbidity currents (Nielsen and Porter, 1984;
Swagor et al., 1976). The slope break, which was interpreted to exist across the basin,
would have concentrated the sand and gravels and these sediments would subsequently
be transported basinward by storm currents forming shoreline-parallel linear ridges
(Griffith et al., 1982; Nielsen and Porter, 1984; Swagor et al., 1976). However, storm-
generated rip-currents were needed to explain the formation of offshore-terrace bars, and
(based on unrealistic storm duration), this was discarded as a viable mechanism in favour
of the turbidity current model (Wright and Walker, 1981).
1.5.3. Stranded Shoreface Deposits
Plint et al. (1986) gave support to a hypothesis presented by DeWeil (1956) that
proposed the Cardium Formation represents multiple regressions of the shoreline during
the Turonian to Coniacian. E1–E7, which were initially thought to represent scouring of
underlying sediments by turbidity currents, were reinterpreted to have formed by wave
and wind erosion during lowstand conditions (Plint et al., 1986). This placed the deposition
of sandstones in a lower to middle shoreface setting, and conglomerates in an upper
shoreface to foreshore environment (Plint et al., 1986). At each surface, the paleo-
shoreline was forced seaward during the lowstand systems tract, with gravel and sand
from Carrot Creek being introduced to the paralic realm via river mouth gravel bars, or
small coarse clastic deltas (Fig. 1.7; Arnott, 1992, 2003; Wadsworth and Walker, 1991).
The fluvially sourced sands and gravels were then redistributed alongshore by wave-
17
generated currents during transgression, which lead to the deposition of the shoreline-
oriented gravel bars found in the Cardium Formation (Arnott, 1992, 2003; Bergman and
Walker, 1987, 1988).
Figure 1.7: Carrot Creek conglomerate depositional model Conceptual diagram showing the orientation and distribution of Carrot Creek conglomerates within the Western Interior Seaway. Coarse clastics were supplied by the Carrot pale-oriver (which has been vertically exaggerated) into the paralic realm. Southeast directed, wave-generated paleocurrents redestributed the sands and pebbles into shoreline oriented ridges, and some of the conglomerates were preserved in locally incised bevels on top of the E5 surface (scoured during lowstand) (Bergman and Walker, 1988).
18
Chapter 2.
2.1. Facies Descriptions
Five main facies have been described, based on the detailed analysis of 38
Cardium Formation cores (Table 2.1). Facies were defined mainly by the combined
siltstone/sandstone content, physical sedimentary structures and ichnology. Bioturbation
intensities were semi-quantified using the Bioturbation Index (BI), described originally by
Reineck (1963) and modified by Taylor and Goldring (1993). This scale is based on grades
of bioturbation that can be discerned with the human eye. The Bioturbation Index has
seven grades that range from no visible bioturbation (BI 0) to completely bioturbated (BI
6).
19
Table 2.1: Facies summary
Summary of five facies identified in east-central Pembina. Sedimentological abbreviations: very fine-grained (vfg), fine-grained (fg), siltstone (slst), sandstone (sst), shale (sh), hummocky cross-stratification (HCS). Trace fossil abbreviations: Asterosoma (As), Chondrites (Ch), Cylindrichnus (Cy), Diplocraterion (Di), Helminthoida (He), Palaeophycus (Pa), Phycosiphon (Ph), Planolites (Pl), Rhizocorallium (Rh), Rosselia (Ro), Scolicia (Sc), Skolithos (Sk), Teichichnus (Te), Thalassinoides (Th), Trichichnus (Tr), Zoophycos (Zo). Bioturbation Index values based on Reineck (1963) and modified by Taylor and Goldring (1993).
Percent
Sandstone/
Siltstone
Grain Size Sedimentology IchnologyBI
(0–6)
Average
Permeability
(geometric
mean)
Average
Porosity
Depositional
EnvironmentContacts
0–10%shale with up to 10%
vfg sand inter beds
Sst/Slst: discontinuous-, parallel-
and wave-ripple laminated
sand beds. Sh: wavy laminaeCh, He, Pa, Ph,
Pl, Sc, Sk0–3 N/A N/A shelf/ramp
L = gradational;
U = gradational
2a 10–30%shale with up to 30%
slst - fg sst1–3 lower offshore
2b 30–50% shale with up to 50%
slst - fg sst1–6
lower to upper
offshore
2c 50–80% shale with up to 80%
slst - fg sst 2–6 upper offshore
50–100%
fg sandstone with up
to 50% shale inter
beds
Sst/Slst: HCS, wave-, inclined
parallel-, combined flow- and
current-ripple laminated
sandstones. Sh: wavy laminae
and beds
As, Ch, Cy, Di,
Ph, Pl, Sk, Te, Th,
Tr, Zo
0–3
lower delta front
(lower shoreface
equivalent)
L = gradational,
erosional, FS; U
= gradational,
erosional
95–100% vfg - fg
Sst/Slst: HCS, wave ripple,
inclined parallel, combined
flow and current ripple
laminated sandstones. Sh:
wavy laminae
N/A 0–1
lower to upper
delta front
(middle shoreface
equivalent)
L = gradational,
erosional; U =
erosional
5a0–50% sand
matrix
sand matrix with cg
sand to cobble clasts
5b0–50% mud
matrix
mud matrix with cg
sand to cobble clasts
7.30%upper shoreface
to foreshore
L = erosional;
U= sharp,
gradational
L= gradational;
U = gradational,
erosional, FS
Facies
Facies 1: Dark grey- to
black silty mudstone to
shale with very fine-
grained sandstone laminae
Facies 3: Massive to
bioturbated sandstone with
parallel and wavy shale
beds
Facies 4: Apparently
structureless to HCS
sandstone
9.90%
16.40%
Facies 2: Dark grey
bioturbated sandy
mudstone to muddy
sandstone
Sst/Slst: discontinuous-, parallel-
, inclined- and wave-ripple
laminated, mudstone rip-up
clasts, HCS, lenticular bedding.
Sh: wavy laminae
As, Ch, Cy, Di,
Gy, He, Pa, Ph,
Pl, Rh, Ro, Sc, Sk,
Te, Th, Tr, Zo
0.69 mD
18.8 mD
Facies 5: Clast- to
matrix-supported
conglomerate
parallel and inclined laminae Ch, Pl, Ph, Th 0–1 84.4 mD
20
2.1.1. Facies 1 (F1): Silty mudstone to shale with very fine-grained sand laminae
Facies 1 comprises weakly to moderately bioturbated (BI 0–3), silty to sandy shale with
rare (0–5%) mm- to cm-scale, very fine-grained sandstone to siltstone beds (Fig. 2.1). The
combined sand/silt content is less than 10%. Discrete sandstone beds are commonly normally
graded, sharp-based, and contain discontinuous parallel- to wave-ripple laminae (Fig. 2.1A).
Coarse sandstone beds and large granules are rare (0–3%), and are organized into poorly defined
pebble horizons that increase in abundance in proximity to Facies 5 (Fig. 2.1B). Nodular siderite
is found throughout.
Burrows are generally diminutive (<2 mm diameter) in size, and the overall trace fossil
diversity is low to moderate. Identified traces include Chondrites, Helminthoida, Palaeophycus,
Phycosiphon, Planolites, Skolithos, and lesser Schaubcylindrichnus. Inoceramid and belemnite
fragments are rare throughout.
Facies 1 Interpretation:
The silty mudstones of Facies 1 are interpreted to have been deposited at or slightly below
effective storm wave base on the shelf / ramp of the Western Interior Seaway. Within this
environment mud is deposited mainly under low-energy ambient weather conditions, and silt- to
sand-sized grains are transported and deposited during and immediately following storm surges
either by wave-orbital motion or via offshore-directed storm-induced currents (Plint and
Macquaker, 2013; Plint et al., 2012). The scoured bases and rare wave-generated sedimentary
structures in these sandstone tempestites of F1 are consistent with this interpretation.
F1 is weakly to moderately bioturbated (BI 1-3) and the trace-fossil suite is typical of the
Zoophycos Ichnofacies (MacEachern et al., 2010). The low to moderate bioturbation intensity and
small diameters of trace fossils reflect infaunal responses to physical-chemical stresses in the
depositional environment; likely reduced oxygen levels (Dashtgard et al., in press; MacEachern
et al., 2010). In contrast, bioturbation is absent to weak in individual silty to sandy tempestites and
is typical of top-down colonization by opportunistic fauna following high energy emplacement of
event beds (Vossler and Pemberton, 1988a).
Coarse sands and pebbles are only found in F1 where it overlies F5 (Fig. 2.1B). The
coarse clastics are interpreted to be tempestites sourced from the laterally adjacent, gravel-
bearing shoreline, wherein the gravel is carried offshore by storm waves.
21
Figure 2.1: Examples of F1
Core photographs of Facies 1: Silty mudstone to shale with very fine-grained sandstone laminae. A) Weakly bioturbated (BI 0–3) laminated silty mudstone with 5–10% siltstone/sandstone content and rare siderite (SID) concretions. The bases of discontinuous’ sandstone tempestites are marked with yellow arrows (6-29-049-08W5, 1502.3 m). B) Mudstone of F1 overlying conglomerate of F5. The mudstone contains 5% scattered coarse-grained sand to pebbles, and fine-grained sandstone to siltstone beds are not evident. The conglomerate bed at the top of the photo is 4 cm thick and occurs within F1 (04-11-048-08W5, 1558.9 m). Trace fossil abbreviations: Asterosoma (As), Chondrites (Ch), Phycosiphon (Ph), Planolites (Pl), and Skolithos (Sk).
22
2.1.2. Facies 2 (F2): Bioturbated sandy mudstone to muddy sandstone with thin sandstone beds
Facies 2 is subdivided into 3 subfacies based on the combined siltstone and sandstone
content.
Facies 2a (F2a): Sandy mudstone with 10–30% siltstone/sandstone content
Facies 2a comprises weakly to moderately bioturbated (BI 0–3) silty to sandy mudstone
with rare (5–10%) mm- to cm-scale, very fine- to fine-grained sandstone beds. The combined
sand/silt content ranges from 10–30%. Siltstone and sandstone is contained either within graded
beds in weakly bioturbated (BI 0–1) sediments, or as interstitial grains distributed in moderately
bioturbated intervals (BI 2–3). Sedimentary structures in sandstone beds include wave ripples
with lesser parallel lamination. Sandstone beds commonly have scoured bases, with mudstone
rip-up clasts, and are graded. Black shale beds and laminae are found throughout and are
discontinuous, wavy-parallel to wavy non-parallel laminated (Fig. 2.2). Medium- to coarse-grained
sand in F2a are present as floating grains or as weakly defined sandstone lenses (Fig. 2.2A).
Burrows are generally diminutive in size (< 2 mm diameter) and the overall trace fossil
diversity is low to moderate (eleven distinct forms encountered). The commonly observed trace
assemblage includes Asterosoma, Chondrites, Helminthoida, Phycosiphon, Planolites,
Rhizocorallium, Schaubcylindrichnus, Scolicia, Teichichnus, Trichichnus, and Zoophycos.
Nodular siderite is found throughout. Pyrite is rare throughout and is present either as scattered
round nodules or occurs in nodular micritic siderite concretions (cm-scale).
23
Figure 2.2: Examples of F2a
Core photographs of Facies 2a: bioturbated sandy mudstone. A) Moderately to intensely bioturbated (BI
2–5) sandy/silty mudstone (15% sand/silt content) with 2% floating coarse-grained sand grains (CS).
Silt/sand content is manifest as discontinuous beds and laminae. Yellow arrows mark bases of discontinuous tempestites and red arrows mark bases of wavy shale laminae (08-11-049-06W5, 1309.0
m). B) Weakly to intensely bioturbated (BI 1–6) sandy/silty mudstone (30% sand/silt content).
Sandstone/siltstone is contained in laterally discontinuous tempestites and in burrow fills (10-26-047-07W5, 1548.8 m). Trace fossil abbreviations: Asterosoma (As), Phycosiphon (Ph), Planolites (Pl), Rosselia (Ro), and Thalassinoides (Th).
Facies 2b (F2b): Sandy mudstone 30–50% siltstone/sandstone content
Facies 2b comprises weakly to moderately bioturbated (BI 1–4) silty to sandy mudstone
with rare to moderate (5–25%) cm-scale, fine- to very fine-grained sandstone beds. The combined
sand/silt content ranges from 30–50%. Siltstone and sandstone is distributed either in weakly to
moderately bioturbated discrete graded beds (BI 1–3) or as interstitial grains mottled by
bioturbation (BI 3–4). Sedimentary structures in sandstone beds include planar- and wave ripple-
24
laminae, wavy-parallel, hummocky cross-stratification, and lenticular bedding (Fig. 2.3A). Locally,
sandstones may appear structureless. Sandstone beds commonly have scour bases with
mudstone rip-up clasts, and are normally graded (Fig. 2.3A). Black shale beds and laminae occur
throughout and are discontinuous, wavy-parallel to wavy non-parallel (Fig. 2.3). Medium- to
coarse-grained sand is rare and occurs as floating grains or as weakly defined lenses, typically in
close stratigraphic proximity to facies contacts.
Burrows are generally diminutive (< 2 mm diameter) to moderate (2–8 mm diameter) in
size, and the overall trace-fossil diversity is 12 (Seilacher, 1974). Chondrites, Cylindrichnus,
Diplocraterion, Helminthoida, Palaeophycus, Phycosiphon, Planolites, Schaubcylindrichnus,
Skolithos, Teichichnus, Trichichnus, and Zoophycos are commonly observed. Nodular siderite is
common within F2b. Pyrite is rare throughout and occurs in nodular micritic siderite concretions
(cm-scale).
25
Figure 2.3: Examples of F2b
Core photographs of Facies 2b: Bioturbated sandy mudstone to muddy sandstone. A) Weakly to moderately
bioturbated (BI 1–4) sandy mudstone (50% combined sand/silt content) with a 4.5 cm thick wavy-parallel
(WP) laminated sandstone tempestite with a scoured base and a mudstone rip-up clast (MR; base of tempestites marked with yellow arrow). Base of wavy shale laminae marked with red arrow (03-07-048-
08W5, 1648.6 m). B) Moderately to intensely bioturbated (BI 3–5) sandy mudstone (40% total sand
content; 03-07-048-08W5, 1647.2 m). C) Moderately bioturbated (BI 4–5) sandy mudstone (45% total sand
content; 15-27-047-07W5, 1529.1 m). Trace fossil abbreviations: Chondrites (Ch), Phycosiphon (Ph), Planolites (Pl), Rhizocorallium (Rh), Rosselia (Ro), Schaubcylindrichnus (Sc), Skolithos (Sk), Teichichnus (Te), Thalassinoides (Th), and Trichichnus (Tr).
Facies 2c (F2c): Muddy sandstones with 50–80% siltstone/sandstone content
Facies 2c comprises moderately to intensely bioturbated (BI 3–5) muddy sandstones with
moderate to abundant (10–35%) cm-scale, fine- to very fine-grained sandstone beds. The
combined sand/silt content ranges from 50–80%. Siltstone and sandstone units display weakly to
moderately bioturbated, discrete graded beds (BI 1–3) or show interstitial grains mottled by
26
bioturbation (BI 3–5). Sedimentary structures in sandstone beds include planar-, inclined- and
wave-ripple laminae, hummocky cross-stratification, and lesser lenticular bedding that is rarely
preserved due to high intensities of bioturbation (Fig. 2.4C). Sandstone beds commonly have
scoured bases with mudstone rip-up clasts (Fig. 2.4D), are commonly normally graded, and are
bioturbated towards the top of the bed. Black shale beds and laminae occur throughout and are
discontinuous, or wavy-parallel to wavy non-parallel laminated (Fig. 2.4). Rare medium- and
coarse-grained sands are rare throughout and are present as floating grains or as weakly defined
pebble lenses.
Burrows in Facies 2c range from diminutive (<2 mm diameter) to robust (>8 mm diameter)
in size. The overall trace-fossil diversity is 16. The trace assemblage includes Chondrites,
Cylindrichnus, Diplocraterion, Helminthoida, Palaeophycus, Phycosiphon, Planolites,
Schaubcylindrichnus, Skolithos, Teichichnus, Trichichnus, and Zoophycos. Asterosoma,
Rosselia, Rhizocorallium, and Thalassinoides also occur rarely in this facies. Pyrite is rare
throughout, and occurs in nodular siderite concretions (cm-scale).
27
Figure 2.4: Examples of F2c
Core photographs of Facies 2c: Moderately to intensely bioturbated sandy mudstone to muddy sandstone. A) Moderately to intensely bioturbated (BI 3–5) muddy sandstone (50% combined siltstone/sandstone content). Bases of wavy shale beds are marked with red arrows (03-07-048-08W5, 1652.3 m). B) Moderately to intensely bioturbated (BI 2–6) muddy sandstone (65% combined siltstone/sandstone content). Bases of discontinuous tempestites are marked with a yellow arrow (03-07-048-08W5, 1652.8 m). C) Weakly to moderately bioturbated (BI 1–4) muddy sandstone (75% combined siltstone/sandstone content). This sample also has a cm-scale wave-ripple (WR) laminated tempestite (11-05-049-07W5, 1434.9 m). D) Weakly to intensely bioturbated (BI 1–5) muddy sandstone (70% combined siltstone/sandstone content) (10-07-048-07W5, 1509.7 m). Trace fossil abbreviations: Asterosoma (As), Chondrites (Ch), Cylindrichnus (Cy), Helminthoida (He), Phycosiphon (Ph), Planolites (Pl), Rosselia (Ro), Schaubcylindrichnus (Sc), Siphonichnus (Si) – red outline, Skolithos (Sk), Thalassinoides (Th), Trichichnus (Tr), and Zoophycos (Zo).
28
Facies 2 Interpretation:
The bioturbated sandy mudstones to muddy sandstones of facies 2a are interpreted to
have been deposited at or just above effective storm wave base in a lower offshore environment.
Facies 2b is interpreted to have been deposited above effective storm wave base, and below fair-
weather wave base in a lower to upper offshore environment. Facies 2c is interpreted to have
been deposited below fair-weather wave base in an upper offshore environment. Within these
environments, mud is deposited mainly under low-energy ambient conditions or by hyperpycnal
plumes initiated during the waning stages of a storm surge resultant from the increase in overland
precipitation and subsequent increased river sediment supply; and the silt- to sand-sized grains
are likely transported and deposited during and immediately following storm surges either by
wave-orbital motion or via offshore-directed storm-induced currents (Mulder and Syvitski, 1995;
Plint and Macquaker, 2013; Plint et al., 2012). The scoured base, and wave-generated
sedimentary structures present within the sandstone deposits in F2 is consistent with this
interpretation. An overall increase in the sandstone/siltstone fraction from F1 to F2 indicates that
deposition occurred in progressively shallowing water depths, initiated by normal regression (Plint
et al., 1986).
The bioturbation intensity, diversity and trace fossil sizes vary between the F2 subfacies.1)
F2a is weakly to moderately bioturbated and the trace-fossil suite is typical of the Cruziana and
Zoophycos Ichnofacies (MacEachern et al., 2010). The low to moderate bioturbation intensity and
small diameters of trace fossils within F2a are a manifestation of animal growth in a physico-
chemically stressed environment. In this case, low oxygen levels likely limit animal size
(Dashtgard et al., in press; MacEachern et al., 2010). Bioturbation is absent to weak within
individual sandstone tempestites, and tempestites increase in thickness and frequency from F1
to F2a. F2b is moderately to intensely bioturbated, and the trace-fossil suite is typical of the
Cruziana Ichnofacies (MacEachern et al., 2010). The bioturbation intensities and moderate trace
fossil diameters within F2b are indicative of limited physico-chemically stresses within this
depositional environment (MacEachern et al., 2010). Bioturbation is absent to weak within
individual sandy tempestites, which increase in thickness and recurrence from F2a to F2b. 3) F2c
is moderately to intensely bioturbated, and the trace-fossil suite is typical of the Cruziana
Ichnofacies (MacEachern et al., 2010). The high bioturbation intensity and moderate to large trace
fossil diameters (Fig. 2.4A; Fig. 2.4D) within F2c are indicative of a depositional environment with
minimal physico-chemical stresses (Dashtgard et al., in press; MacEachern et al., 2010).
Bioturbation is absent to weak within individual sandstone storm deposits which increase in
thickness and frequency from F2b to F2c. The nature of bioturbation within individual tempestites
29
in F2 is typical of top-down colonization by opportunistic fauna (Pemberton and MacEachern,
1997; Vossler and Pemberton, 1988b)
The coarse-grained sands and pebbles found in F2 are interpreted to be tempestites
sourced from the laterally adjacent shallow-marine environments that contain gravel, wherein the
gravel is carried offshore by storm waves (e.g., Fig. 2.2A).
2.1.3. Facies 3 (F3): Massive to bioturbated sandstone with thin mudstone and siltstone beds
Facies 3 comprises structureless to weakly bioturbated (BI 0–2) muddy sandstone to
sandstone, with absent to abundant (0–50%) mm- to cm-scale mudstone beds (locally up to 80%
wavy-bedded shale). The shale beds commonly have scoured bases and are either undulatory-,
wavy non-parallel, or planar-laminated (Fig. 2.5). The sandstones are locally massive to
hummocky cross-stratified or wave-ripple laminated. Other sedimentary structures include
inclined and parallel, combined-flow and current ripple-laminae that are commonly demarcated
by carbonaceous detritus (Fig. 2.5D). Sandstones commonly contain mudstone rip-up clasts and
nodular siderite (Fig. 2.5B). Pyrite is rare throughout, and occurs in nodular micritic siderite
concretions (cm-scale).
Burrows in F3 are generally diminutive (< 2 mm diameter) to moderate (2–8 mm diameter)
in size, and the overall trace-fossil diversity is 13 (Fig. 2.5). Chondrites, Cylindrichnus,
Diplocraterion, Phycosiphon, Planolites, Skolithos, Teichichnus, Trichichnus, and Zoophycos with
rare Asterosoma and Thalassinoides are commonly observed in muddier (10–20% mud)
sandstone intervals. Discrete wavy-bedded shales are bioturbated exclusively with Chondrites (BI
0–2). Sandstone intervals are weakly bioturbated (BI 0–1) and only Gyrochorte are present.
Facies 3 Interpretation:
Facies 3 sandstones are considered to be deposited on the lower delta front (lower
shoreface equivalent) of a wave-dominated delta. Within this depositional environment, high
volumes of mud was delivered from rivers to the delta front during and immediately following
periods of high elevated discharge (Mulder and Syvitski, 1995; Wheatcroft, 2000). When
suspended sediment concentrations and water salinity parameters allow, these muds were
transported via bottom-hugging hyperpycnal flows onto the delta front (Bhattacharya and
MacEachern, 2009). These mud-rich deposits can mantle existing bedforms and be remobilized
by storm waves (Fig. 2.5).
30
F3 is weakly bioturbated and the trace-fossil suite is typical of a stressed expression of
the Cruziana Ichnofacies (MacEachern et al., 2005). Only facies-crossing, opportunistic fauna are
able to inhabit such deltaic environments, which regularly experience fluctuations in water
salinities, oxygen levels, and water turbidity (Gingras and MacEachern, 1998; MacEachern et al.,
2005). Bioturbation is highly variable within this heterolithic facies and it is dependent on the
periodicity of seasonal and annual storm events. Sandstone and mudstone layers devoid of
bioturbation represent periods with high sediment influx and when hyperpycnal conditions
dominated over hypopycnal (Fig. 2.5C). Bioturbated muddy sandstones are indicative of
prolonged ambient conditions allowing for the colonization by opportunistic fauna (Fig. 2.5A;
MacEachern et al., 2005).
31
32
Figure 2.5: Examples of F3
Core photographs of Facies 3: Sandstone with thin mudstone laminae and beds. A) The lower portion of the sample comprises absent to weak bioturbation (BI 0–2) in stacked hummocky cross-stratified (HCS) tempestites that grade into wavy shale laminae (base of individual tempestites marked with yellow arrow). Upper portion of sample comprises intensely bioturbated (BI 5) muddy sandstone (70% combined sandstone/siltstone content; 06-29-049-08W5, 1490.8 m). B) Absent to moderately bioturbated (BI 0–3) stacked wavy parallel- to combined-flow ripple laminated tempestites (80% combined siltstone/sandstone content). Base of middle tempestite (marked by yellow arrow) is lined with mudstone rip-up clasts (MR). The middle sandstone bed is moderately bioturbated (BI 3) with bioturbation increasing towards the top of the bed. This reflects top-down post-depositional colonization of the tempestite (03-07-048-08W5, 1651.0 m). C) Sandstone with mm- cm-scale wave-ripple and wavy shale laminae. Base of shale laminae is marked with a red arrow (06-29-049-08W5, 1492.2 m). D) Sandstone with mm- to cm-scale wave-ripple and wavy parallel shale laminae (15-27-047-07W5, 1525.8 m). E) Wave- to (WR) combined flow-ripple (CF) laminated sandstone with mm-scale wavy shale laminae (03-07-048-08W5, 1650.1 m). Trace fossil abbreviations: Asterosoma (As), Chondrites (Ch), Gyrochorte (Gy), Palaeophycus (Pa), Phycosiphon (Ph), Planolites (Pl), Rosselia (Ro), Siphonichnus (Si), Skolithos (Sk), and Zoophycos (Zo).
2.1.4. Facies 4 (F4): Unbioturbated, massive- to hummocky cross-stratified sandstone
Facies 4 comprises apparently structureless to hummocky cross-stratified (HCS)
sandstones (Fig. 2.6). Beds are dominantly massive, hummocky cross-stratified, or wave-ripple
laminated, although some beds also show lesser combined-flow and current-ripple laminae.
Parallel, combined flow ripple, and wave ripple laminae are commonly lined with carbonaceous
detritus (Fig. 2.6). Sandstones also commonly contain mudstone rip-up clasts at the bases of
beds (Fig. 2.6B).
Burrows in F4 are generally diminutive in size and the overall trace-fossil diversity is very
low. Clean sandstone intervals are weakly bioturbated (BI 0–1) and only Macaronichnus is
observed. Pyrite is rare throughout, and occurs in nodular micritic siderite concretions (cm-scale).
Sandstones are also locally calcite cemented, which coincides with visibly reduced oil staining
(Fig. 2.6D).
Facies 4 Interpretation:
Facies 4 sandstones are interpreted to have been deposited on the lower to upper delta
front (middle shoreface equivalent) front of a wave-dominated delta. This environment is
characterized by very high sedimentation rates, which is the result of the abrupt velocity drop
across the transition from flow confined to the channel to unconfined flow in the shallow-marine
environment. Wave processes extensively rework the upper to middle delta front and as a result,
these deposits bear many similarities to wave-dominated shorelines.
33
Bioturbation is generally absent in F4 and this is attributed to the physico-chemical
stresses affecting the upper delta front (Fig. 2.6). These include extremely high sedimentation
rates, low water salinity, and elevated turbidity (MacEachern et al., 2005). The only trace fossil
found in F4 are diminutive Macaronichnus, which have been shown to have preservation potential
in environments with high sedimentation rates (Clifton and Thompson, 1978).
34
Figure 2.6: Examples of F4
Core photographs of Facies 4: Unbioturbated, massive to hummocky cross-stratified (HCS) sandstones. A)
Carbonaceous detritus-rich HCS sandstone (03-07-048-08W5, 1642.9 m). B) Carbonaceous detritus rich
HCS sandstone. Mudstone rip-up (MR) clasts are evident towards the bottom of the sample (03-07-048-
08W5, 1640.5 m). C) Hummocky cross-stratified (red arrow) to combined flow-rippled (yellow arrow)
stacked tempestites. The base of the upper tempestite is scoured and undulatory, reflecting scouring in
association with deposition of the overlying bed (10-10-049-08W5, 1539.9 m). D) Sandstone with mud and
carbonaceous detritus lining inclined parallel laminae. Sample is locally calcite cemented (CC) which
coincides with a visible decrease in oil stain (11-05-049-07W5, 1435.3 m).
35
2.1.5. Facies 5 (F5): Clast- and matrix-supported conglomerate
Facies 5 is subdivided into 2 subfacies based on the matrix types present.
Facies 5a (F5a): Clast-supported polymictic conglomerates
Facies 5a comprises polymictic, clast-supported, granule to medium-pebble
conglomerates. F5a is dominantly clast-supported with medium- to coarse-grained sand matrix.
No grading is visible within F5a conglomerates. Sedimentary structures are rarely observed,
although inclined and parallel laminae and bedding occurs locally, particularly where intervening
sandstone and mudstone beds are present (Fig. 2.5B). Clast composition is dominated by chert
with lesser quartz and lithic fragments. Clasts are sub-rounded to well-rounded. Bioturbation is
mainly absent (BI 0–1) with only firmground Thalassinoides present noted (Fig. 2.7A).
Facies 5b (F5b): Mud matrix-supported polymictic conglomerates
Facies 5b comprises polymictic, matrix-supported, granule to medium-pebble
conglomerates. F5b is dominantly matrix-supported with mud to fine-grained silt matrix. No
grading is visible within F5b conglomerates. Sedimentary structures are rarely observed, although
inclined and parallel laminae and bedding occurs locally (Fig. 2.5B). Nodular siderite concretions
are abundant and are most common in intervals with a high mud-matrix component. Complete
sideritization of the mud matrix also occurs in some intervals (Fig. 2.7D). Clast composition is
dominated by chert with lesser quartz and lithic fragments. Clasts are sub-rounded to well-
rounded. Bioturbation is mainly absent (BI 0–1) with only Chondrites, Planolites and Phycosiphon
being observed within isolated mud dominated intervals.
Facies 5 Interpretation:
The clast-supported conglomerates (F5a) of are interpreted to have been deposited in an
upper shoreface to foreshore environment (or proximal delta front) during the later stages of
marine progradation or subsequent transgression (mud matrix-supported; F5b). Coarse clastics
sourced from fluvial point sources and eroded strandplains were deposited proximal to the
shoreline and subjected to extensive winnowing and reworking by wave-action; this is consistent
with the high textural maturity and well-sorted character of F5a progradational conglomerates
(Fig. 2.7). F5 also has mud-supported conglomerates of variable thicknesses (F5b). While it is
possible that thin bedded mud-supported conglomerates could have formed during the later
stages of progradation when mud-laden waters can percolate through coarse beach deposits
36
depositing mud matrix; the overall thicknesses viewed within east-central Pembina suggests that
the majority were formed during the initial stages of marine transgression (Dashtgard and
Gingras, 2007; Dashtgard et al., 2006).
The presence of firmground Thalassinoides and the Glossifungites Ichnofacies (Fig. 2.7A)
is evidence that some of the exhumed substrates were subjected to early diagenesis and
therefore represent hardground conditions prior to deposition (MacEachern et al., 2010). The
overall lack of trace fossil diversity and low bioturbation intensity noted in F5 is a result of the poor
preservation potential of ichnological structures within conglomerates (Dashtgard et al., 2008b).
37
38
Figure 2.7: Examples of F5
Core photographs of Facies 5: Clast- to matrix-supported conglomerates. A) Sample with a burrowed contact between F5a and F4 below (yellow dashed line). The base of the F5a conglomerates is erosional. The upper clast-supported conglomerate has medium- to coarse-grained sand matrix. Clasts are polymictic, well-rounded and vary in size from 0.2–1 cm. There is a vertical firmground Thalassinoides (Th) that extends from the F4-F5a contact into F4 (15-27-047-07W5, 1522.3 m). B) Mud-matrix supported polymictic conglomerate (F5b). There is a cm-scale moderately inclined shale bed in the middle of the sample (15-27-047-07W5, 1521.8 m). C) Mud-matrix supported polymictic conglomerate (F5b). Clast diameters range from 0.25 mm (medium-grained sand) to 1 cm (small pebble) (15-27-047-07W5, 1520.2 m). D) Siderite cemented mud-matrix polymictic conglomerate with well-rounded 0.5 mm to 2 cm (medium pebble) clasts (F5b). Sample has a sharp inclined contact with a sand matrix-supported polymictic conglomerate (F5a) in the upper left portion of the sample (03-07-048-08W5, 1636.42 m).
2.2. Facies Associations
Two vertical facies associations are observed in the cores logged for this study.
2.2.1. Facies Association One (FA1): Sandying-upwards shelf/ramp to upper delta front (middle shoreface equivalent) deposits
Facies association 1 (FA1) includes sanding-upwards successions (F1 – F2a – F2b – F2c
– F3 – F4) that represent normal progradation from a shelf/ramp setting (F1) to an upper delta
front (middle shoreface equivalent) environment (F4; Fig. 3.5), or normal progradation from a
shelf/ramp (F1) to the upper offshore (F2c). Where the entire progradation sequence is complete,
the poorly sorted clast-supported conglomerates of F5a overlie shoreface sandstones of F4.
Internal flooding surfaces often exist separating thinner sanding-upward successions F1 – FA2
(a/b/c) below from thicker more complete FA1 successions above (F2a – F2b – F2c – F3 – F4).
Complete FA1 successions that do not contain internal flooding surfaces are rare. FA1 has a
gradational lower contact with the underlying Blackstone Formation and an upper sharp erosional
upper contact with overlying progradational clast-supported or mud-supported transgressive
conglomeratic deposits (FA2). The contacts between bioturbated facies in FA1 (F1-F2) are
gradational and are characterized by an increase in combined siltstone and sandstone content.
Several allogenic and autogenic surfaces exist within FA1 and it is common for bioturbated facies
with lower sandstone/siltstone contents to overlie sandier and siltier units. Additionally, deltaic
deposits may transition to normal shoreface deposits and vice versa as a result of autogenic lobe
switching. The internal flooding surfaces noted above (allogenic surfaces) are locally marked by
39
scattered coarse sands to pebbles and siderite nodules. As many as five of these allogenic and
autogenic diastems were noted in some cores. The thickness of FA1 ranges from 6 – 13 m.
2.2.2. Facies Association Two (FA2): Conglomeratic Transgressive Deposits
F1 and F5 comprise FA2 and were deposited in an upper shoreface to foreshore
environment during transgression and during the later stages of marine progradation. The
transgressive surface of erosion upon which the conglomerates are deposited is highly irregular,
with many steps and lows along its extent (Leggitt et al., 1990). This surface was locally
subaerially exposed during forced regression, and the erosional topography controlled the
distribution and character of the transgressive conglomerates within the Cardium Formation
(Krause et al., 1994; Walker and Eyles, 1991). As a result, the contact between FA2 with FA1 is
irregular and has highly variable vertical relief across the study area. The contacts between mud-
supported (F5b) and sand-supported conglomerates (F5a) are typically gradational and are
marked by an increase in siderite cementation as they grade from sandy to muddy matrices. While
no reproducible stacking pattern between sand- and mud-matrix supported conglomerates was
observed, the poorly sorted mud matrix-supported (transgressive) conglomerates (F5b) often
overlie the (progradational) clast-supported conglomerates (F5a). F1 always gradationally
overlies F5 conglomerates and was deposited during the later stages of transgression. The
bioturbation intensity is absent to weak (BI 0–1) within F5, and this reflects the poor preservation
potential of trace fossils in conglomerates, while the bioturbation intensity is absent to moderate
(BI 0–3) within F1 mudstones. The preserved thickness of F5 is highly variable depending on the
proximity to steps or lows along the E5 surface and ranges from 1 cm – 8 m (Fig. 2.8, Fig. 2.9),
while the thickness of FA2 as a whole is unknown as cored intervals do not include the full F1
thickness in any well analyzed.
2.3. Cardium Type Logs
The gamma-ray and resistivity log responses of two wells (03-07-048-08W5, 10-17-049-
06W5) within the study area are shown (Fig. 2.8; Fig. 2.9). The two wells show the distribution of
facies and their log responses along deposition dip from the SW (03-07-048-08W5) to NE (10-17-
049-06W5) portions of the study area. Two pronounced sandying-upwards successions are
shown in the SW section, which are capped by a several meter-thick conglomerate unit. By
40
contrast, one sandying upwards succession is capped by a sub-metre thick conglomerate unit
characterizes the NE area. The two log profiles show the differences in gamma-ray responses for
the same facies across the study area, as well as the corresponding resistivity responses.
Figure 2.8: Core litholog 03-07-048-08W5
41
Core litholog with gamma-ray and resistivity log profiles for 100/03-07-048-08W5/0 representing the vertical facies changes within the SW part of the study area. The well was chosen because it is one of the best preserved and newest cores logged (RR: 1988-10-07), and it is one of the few that contains all described facies and facies associations. Sandstone grain size is very fine upper throughout. Bioturbation Index, after Taylor and Goldring (1993), is defined in the legend (Fig. 2.10). Sandstone grain size remains consistent throughout the section (fine upper to fine lower).
42
Figure 2.9: Core litholog 10-17-049-06W5
Core litholog with gamma-ray and resistivity log profile for 100/10-17-049-06W5 representing the vertical facies changes within the NE part of the study area. Bioturbation index, after Taylor and Goldring (1993), is defined in the legend (Figure 10). Sandstone grain size remains consistent throughout the section (fine upper to fine lower).
Figure 2.10: Cardium type log legend
Legend of symbols used for Cardium type log sections (Fig. 2.8, Fig. 2.9).
43
Chapter 3. Permeability Heterogeneity in Bioturbated Strata, Cardium Formation, Pembina Field, and the Identification of Potential Waterflood Opportunities1
1A version of this chapter is intended for publication in the AAPG Bulletin.
3.1. Introduction
Bioturbated sediments representing distal expressions of paralic depositional
environments are increasingly being exploited for oil in the super-giant Cardium Formation
reservoir, Pembina Field, Alberta, Canada. Oil exploitation from these sedimentary strata was
previously was considered uneconomic due to the limited vertical and horizontal connectivity
between permeable beds. However, recent use of horizontal drilling and multi-stage hydraulic
fracturing has enabled the economic exploitation of hydrocarbons from these reservoirs. This
approach has unlocked an additional 1.0 billion barrels of potential reserves, raising the total
reserve estimate for the Pembina-Cardium Formation to 10.4 billion barrels (Krause et al., 1994;
New Technology Magazine, 2011). To assess the viability of waterflooding these strata and to
determine the reservoir controls on production, bioturbated reservoirs in the Cardium Formation
of east-central Pembina Field are evaluated. Full diameter- and core plug-permeability data are
compared to production data and to sedimentary facies to determine which factors most influence
horizontal well production in east-central Pembina.
Studies of bioturbated reservoirs have shown that bioturbation can either reduce (La Croix
et al., 2013; Pemberton and Gingras, 2005; Tonkin et al., 2010) or enhance primary porosity and
permeability (Dawson, 1978; Gingras et al., 2007; Gingras et al., 2004a; Gingras et al., 1999;
Gingras et al., 2004b; La Croix et al., 2013; Lemiski et al., 2011; MacEachern and Gingras, 2007;
Pemberton and Gingras, 2005; Zenger, 1992). The degree to which the reservoir is affected is
largely dependent on the magnitude of bioturbation, nature of the trace-fossil assemblages, fill of
the burrows, and the overall facies characteristics (Hsieh et al., 2015). It is generally accepted
that moderately bioturbated facies (BI 2–3), dominated by grain-selective (i.e., coarser-grained fill
than surrounding matrix), horizontal and vertical feeding strategies (e.g., Chondrites, Planolites,
Skolithos, Thalassinoides), exhibit enhanced permeability, because vertical burrows connect high
permeability horizontal beds. In intensely bioturbated facies (BI 4–6), diminished permeabilites
44
persist as a result of full admixing (homogenization) of high permeability sand/silt layers with low
permeability clay.
The Cardium Formation at Pembina is considered to be a dual-permeability system,
wherein sand-filled horizontal and vertical burrows are largely permeable, and the matrix is
effectively impermeable (Pemberton and Gingras, 2005; Solano et al., 2012). Dual-permeability
systems commonly have enhanced effective permeability with high permeability layers are
connected via horizontal and vertical burrow networks. However, the degree to which bioturbation
has altered primary porosity and permeability at Pembina has not previously been evaluated. To
that end, the impact of bioturbation on primary horizontal well production and its potential effects
on horizontal water flooding is unknown.
Unconventional, low-permeability light-oil (light-tight oil or LTO) reservoirs are broken
down into three contrasting play types: tight oil, shale oil, and halo-oil plays (Clarkson and
Pedersen, 2011). The distinguishing factors between these three play types is the source of the
oil (e.g., the reservoir is also the source) and the average matrix permeability. Tight-oil plays have
very low matrix permeabilities (< 0.1 mD) and the hydrocarbon source is distinct from the reservoir
(Clarkson and Pedersen, 2011). Shale oil plays are those wherein the hydrocarbon source is also
the reservoir, and the matrix permeability is very low (generally < 0.1 mD). Halo-oil plays refer to
production of bypassed pay proximal to existing conventional production, but where low reservoir
permeabilities limit the economic exploitation of hydrocarbon using vertical and horizontal wells.
Exploitation of oil from halo-oil plays requires multi-stage hydraulic fracturing along horizontal
wellbores (Clarkson and Pedersen, 2011). The focus of this study is halo-oil production from the
Cardium Formation of the Pembina Field, in bioturbated reservoirs that exhibit relatively high
matrix permeabilities (0.1–10 mD).
3.1.1. Stratigraphy and Paleogeography
The Upper Cretaceous Cardium Formation grades upwards from marine shales of the
Blackstone Formation, and passes upwards gradually into marine shales of the Wapiabi
Formation (Fig. 3.1; Krause et al., 1994). The Cardium Formation is part of the regionally
extensive Colorado Group, which reaches 1200 m in thickness in the Alberta foothills (Bloch et
al., 1993). The Colorado Group is a dominantly eastward-tapering marine shale package that
contains at least three sandstone-dominated units: the Basal Colorado, Viking fm, and Cardium
fm (Bloch et al., 1993).
45
Figure 3.1: Cardium Formation Stratigraphy
Chronostratigraphic and lithostratigraphic breakdown of the Cretaceous through the central plains, Alberta. Shown on the chart are the names of bedrock strata from the Lower (144 Ma) to Upper Cretaceous (66.4 Ma). The Cardium Formation (red rectangle on diagram) is part of the Colorado Group and overlies the Blackstone Formation and underlies the Wapiabi Formation. Modified from (ERCB, 2013).
46
Cardium Formation deposition occurred during the Cenomanian and Turonian when
the Cretaceous global sea-level was near an all-time high (Smith, 1994). Deposition
occurred along the western margin of the Western Interior Seaway and sediments were
sourced from the Cordillera to the west (Fig. 3.2; Williams and Stelck, 1975). Following the
early stages of Cardium deposition, there was an overall lowering of relative sea-level
causing the eastward and southeastward progradation of the shoreline (Krause et al.,
1994). At Pembina, this progradation is typified by coarsening-upward parasequences of
bioturbated sandy mudstones to hummocky cross-stratified sandstones interpreted to
reflect normal progradation from an offshore environment to the shallow marine (lower
shoreface to delta front). Mudstone to sandstone successions are overlain unconformably
by foreshore conglomerates (deposited during the lowstand to falling stage systems tract)
that were reworked during subsequent transgression. Several cycles of relative sea level
rise and fall led to the deposition of multiple parasequences, all of which are separated by
widespread marine flooding surfaces.
47
Figure 3.2: Cardium Paleogeography
Paleogeographic reconstruction of the Western Interior Seaway of North America during the early Turonian (Williams and Stelck, 1975). Paleolatitudes are from Irving et al. (1993).
3.1.2. Study Area and Pembina Development History
Research was focused on the Cardium Formation in east-central Pembina Field
(Township 47–50; Range 4–9W5) of Alberta (Fig. 3.3). As of October, 2014, the study area
contains 2527 vertical wells and 374 horizontal wells. East-central Pembina has had extensive
historical development targeting the conventional conglomerate and sandstone deposits, as well
as recent development focused on the bioturbated sandy mudstones to muddy sandstone
deposits. The vertical and horizontal wells within this area also have an abundance of core, core
analysis, and production data which were imperative for the undertaking of this study.
48
Figure 3.3: Study Area
Maps showing: (A) the location of the Pembina Field on a paleogeographic map of the Cardium Formation in Alberta, Canada (after Krause et al., 1994); (B) the location of the study area within the Pembina Field, and; (C) the location of logged cores (yellow stars) and logged cores that were also analyzed for micropermeability values (green stars).
The Cardium Formation (Pembina Field) was discovered in 1953 when Socony Vacuum
Exploration (present day ExxonMobil) drilled the Socony Seaboard Pembina No. 1 discovery
wildcat well (100/04-16-048-08W5; Nielsen, 1957; Parsons and Nielsen, 1954). The Socony
49
Seaboard Pembina No. 1 produced hydrocarbons from thick shallow marine sandstone and
conglomerates. To date, the discovery well has produced over 865,000 bbl of oil and 360,000 mcf
of gas (Nielsen, 1957; Nielsen and Porter, 1984; Parsons and Nielsen, 1954). Enhanced oil
recovery schemes (EOR; waterflooding) began in 1960 following seven years of highly variable
success within Pembina using primary production. Strong production continued until the late
1980s, at which point it was believed that the field was nearing maturity (Krasey, 1985; Todd and
Grand, 1993). Other enhanced oil recovery schemes, including CO2 injection, were attempted in
Pembina in the years to follow (Dashtgard et al., 2008a). While horizontal wells were drilled at
Pembina prior to 2008, the introduction of horizontal wells with multi-stage hydraulic fracturing in
2008 brought about a resurgence of interest in the Cardium Formation and the Pembina Field in
particular (Clarkson and Pedersen, 2011). To date, over 2700 horizontal wells have been drilled
into the Cardium Formation, including 951 within the Pembina Field.
3.2. Methods
Data was compiled from 38 cores and 171 wireline logs for a total of 209 total wells (Fig.
3.3c). When selecting cores and wireline logs for inclusion in this study, preference was given to
the most recently drilled wells, and especially those with gamma-ray, resistivity, and neutron and
density porosity log profiles. Core analysis data (e.g., porosity and permeability measurements)
were obtained from Accumap and were compiled and analyzed using Microsoft Excel.
Geophysical well-log responses were compared to core descriptions to determine the log
character of facies, and then facies isopach mapping was undertaken using the log responses for
the 209 wells.
Cardium fm facies were subdivided based on the visual sandstone/siltstone percentage
(including all discrete beds, burrows, and interstitial grains), grain-sizes, physical sedimentary
structures, and ichnology. Bioturbation intensities were semi-quantified using the Bioturbation
Index (BI), described originally by Reineck (1963)) and modified by Taylor and Goldring (1993).
This scale is based on grades of bioturbation that can be discerned with the human eye. The
Bioturbation Index has seven grades that range from no visible bioturbation (BI 0) to completely
bioturbated (BI 6).
50
3.2.1. Pressure Decay Profile Permeameter (PDPK) Analyses
A total of 44 samples from 11 wells (Fig. 3.3c) were chosen for Pressure Decay Profile
Permeameter (PDPK or micro-perm) analysis. The wells chosen for sampling have good overall
core integrity, a core diameter >7.5 cm, and contain bioturbated sandy mudstones to muddy
sandstones. Sample lengths range from 6–25 cm, and between 11 and 23 PDPK measurements
were taken per core sample for a total of 758 datapoints. Measurement locations on each slab
were carefully chosen to ensure permeability values were collected for all lithologies (e.g., sand-
filled burrow, parallel laminated mudstone) in each sample.
Core samples selected for PDPK measurements were slabbed to 1/3 of their original
diameter. Cut samples were lightly sandblasted to ensure that a good seal formed between the
slabbed surface and the O-ring attached to the probe tip (0.4 cm diameter) of the PDPK-400
machine. Samples were then cleaned with a toluene solution to chemically remove any mobile
hydrocarbons and placed in an oven to allow the sample to fully dry. Sample preparation and
permeability measurements were performed at the Core Laboratories facilities in Calgary, Alberta.
Once the seal between the O-ring and the rock was confirmed gas was allowed to flow from the
PDPK-400 into the core at 70 kPa (initial upstream flow pressure). The decay of the initial pressure
was measured against time and the collected data was corrected for Klinkenberg-slippage effects
(Fathi et al., 2012). Klinkenberg-slippage correction accounts for the fact that gas molecules
injected into a sample move through the centre and edges of pore throats at the same speed,
whereas liquids (i.e., oil) do not. Correction of the data yields Klinkenberg-corrected liquid
equivalent permeability measured in microdarcys.
3.2.2. Permeability Calculations
An equivalent permeability value (𝒌𝒆𝒒) was estimated using the arithmetic, geometric, and
harmonic means. Assuming steady-state, single-phase flow, the upper bound represents the
equivalent permeability along layering in a perfectly laminated system and is equal to the
arithmetic mean (Eq. 1):
𝒌𝒂𝒓𝒊𝒕𝒉𝒎𝒆𝒕𝒊𝒄 = ∑𝒌𝒊𝒅𝒊
𝒅
𝒏
𝒊=𝟏
(Eq. 1)
51
where 𝒌𝒊 is the permeability of an individual layer, 𝒅𝒊 is the thickness of that layer, and 𝒅 is the
total thickness of the facies under investigation. The lower bound of this analysis is equivalent to
the harmonic mean (Eq. 2), which is the permeability across layering in a perfectly laminated
system:
𝒌𝒉𝒂𝒓𝒎𝒐𝒏𝒊𝒄 =𝟏
∑𝒅𝒊
𝒌𝒊𝒅𝒏𝒊=𝟏
(Eq. 2)
where 𝒌𝒊 is the permeability of an individual layer, 𝒅𝒊 is the thickness of that layer, and 𝒅 is
the total thickness of the facies under investigation. The actual effective permeability (𝒌𝒆𝒒) —
a single permeability value that best represents a heterogeneous system as if it were
homogeneous — is equivalent to the geometric mean (Eq. 3). This value lies within the upper
and lower bounds described above and is the best analog for single phase-flow in a natural
reservoir where fluid flow can occur in all directions (Freeze and Cherry, 1979; Gelhar, 1986;
Warren and Price, 1961; Wiener, 1912).
𝐥𝐧 (𝒌𝒈𝒆𝒐𝒎𝒆𝒕𝒓𝒊𝒄) = ∑𝐥𝐧 (𝒌𝒊)𝒅𝒊
𝒅
𝒏
𝒊=𝟏
(Eq. 3)
In order to calculate effective permeabilities for the heterogeneous reservoir under
investigation, the geometric mean equation (Eq. 3) described above was used. It was applied
to three hydrodynamically similar units: 1) bioturbated reservoir ranging from 30–80%
combined sand/silt content; 2) conventionally targeted sandstone reservoirs; and 3)
conventionally targeted conglomeratic reservoirs.
Statistical analyses were completed on core analysis data for each individual
hydrodynamic unit within a single well before the geometric mean was calculated. Only
permeability values that were determined to lie within the statistically defined upper and lower
bounds were used. This is computed using an interquartile range (IQR), which is defined as 50%
of the dataset that lies between the 1st and 3rd quartile (Upton and Cook, 1996). The upper and
lower bounds are therefore (Eq. 4):
52
Upper Bound = Q1 + 1.5*IQR
Lower Bound = Q3 – 1.5*IQR
(Eq. 4)
Only permeability data points that lie within the upper and lower bounds were used
in order to retain the integrity of the dataset and to ensure geometric mean values had statistical
significance. This methodology ensured that anomalously high or low permeability measurements
within an individual hydrodynamic unit would not skew the representative geometric mean values
calculated.
3.2.3. Contouring (using Golden Software Surfer®)
Sandstone isopach thicknesses were calculated from the 209 vertical wells, and variable
sandstone gamma-ray, resistivity, and porosity cut-offs were used depending on proximity to well
control points (38 logged wells). Variable cut-offs were used in order to minimize sedimentological
(e.g., radioactivity of clay minerals) and operational bias (e.g., data collected over several
decades), which exists within the study area. Where well-log data was limited or outdated,
porosity and permeability cut-offs were applied to core analysis data to determine the contact
between bioturbated sandy mudstone and sandstone facies.
Advanced kriging, based on deposition trends mapped in the study area
(anisotropy: 1.5, angle: 150°) was applied to the datasets to interpolate between datapoints and
produce contour maps that extend across the entire study area. Data northwest of the Pembina-
Cardium pool boundary were removed from contour maps (insignificant thickness and extent).
Data poor areas exist in the NE, SE, and NW portions of the study area, as well as the NW-SE
trending embayment located in the east-central portion of the study area.
3.3. Results
3.3.1. Facies
Five facies are defined in the Cardium Formation and across the study area (Table 3.1).
Of the 5 facies, Facies 2 (F2) includes bioturbated sandy mudstones and muddy sandstones
(target reservoir facies in this study), and is subdivided into 3 subfacies based on the total
53
percentage of combined sandstone and siltstone. Facies 2 represents sediments interpreted to
be deposited below fair-weather wavebase and above storm-wave base; hence, they are
interpreted as offshore to shoreface (prodelta to distal delta front equivalent) deposits. Below are
descriptions of the main reservoir facies (F2b and c, F3–5), with a focus on how sedimentologic
and ichnologic characteristics impact permeability.
Subfacies 2a (F2a) comprises weakly to moderately bioturbated (BI 0–3) silty to sandy
mudstone with rare (5–10%) mm- to cm-scale, very fine- to fine-grained sandstone beds (Table
3.1; Fig. 3.4A). The combined sand/silt content ranges from 10–30%. The sandstone-siltstone
content of F2a is below the 30% threshold for economic exploitation, and hence F2a is not
included in reservoir mapping.
Subfacies 2b (F2b) comprises weakly to moderately bioturbated (BI 1–4) silty to sandy
mudstones with rare to moderate (5–25%) cm-scale, fine- to very fine-grained sandstone beds
(Fig. 3.4B). The combined sand/silt content ranges from 30–50%, and siltstone and sandstone is
distributed either in weakly to moderately bioturbated discrete graded beds (BI 1–3), or as
interstitial grains mottled by bioturbation (BI 3–4). Black shale beds and laminae occur throughout
and are discontinuous, and wavy-parallel to wavy non-parallel laminated (Fig. 3.4B). Medium- to
coarse-grained sand is rare throughout and occurs as floating grains or as weakly defined
sandstone lenses, commonly in close proximity to facies contacts. Sand-filled burrows are
generally diminutive (< 2 mm diameter) to moderate (2–8 mm diameter) in size and the overall
trace-fossil diversity is 12 (Table 3.1; Seilacher, 1974).
Subfacies 2c (F2c) comprises moderately to intensely bioturbated (BI 3–5) muddy
sandstones with moderate to abundant (10–35%) cm-scale, fine- to very fine-grained sandstone
beds (Fig. 3.4C). The combined sand/silt content ranges from 50–80%. Siltstone and sandstone
content is manifest either as weakly to moderately bioturbated, discrete graded beds (BI 1–3) or
as interstitial grains mottled by bioturbation (BI 3–5). Black shale beds and laminae occur
throughout and are discontinuous, and wavy-parallel to wavy non-parallel laminated. Sand-filled
burrows in Facies 2c range from diminutive (< 2 mm diameter) to robust (> 8 mm diameter) in
size. The overall trace-fossil diversity is 16 (Table 3.1; Seilacher, 1974).
Facies 3 comprises structureless to weakly bioturbated (BI 0–2) muddy sandstone (> 80%
combined silt/sand content) to sandstone, with absent to abundant (0–50%) mm- to cm-scale
shale beds (locally up to 80% shale; Fig. 3.4D). The shale beds commonly have scoured bases
and are either undulatory-, wavy non-parallel, or planar parallel laminated (Fig. 3.4D). Sandstones
are locally massive to hummocky cross-stratified (HCS) or are wave-ripple laminated. Other
sedimentary structures include inclined and parallel, combined-flow ripple and current ripple
54
laminae that are commonly lined with carbonaceous detritus (Fig. 3.4D). Sand-filled burrows in
F3 are generally diminutive (< 2 mm diameter) to moderate (2–8 mm diameter) in size and the
overall trace-fossil diversity is 13 (Table 3.1; Seilacher, 1974).
Facies 4 comprises apparently structureless to HCS sandstones. Beds are dominantly
massive, contain HCS, or are wave-ripple laminated, although some beds contain parallel,
inclined, combined-flow ripple and current ripple laminae (Fig. 3.4E). Parallel, combined flow and
wave-ripple laminae are commonly lined with carbonaceous detritus (Fig. 3.4E). Burrows in F4
are generally diminutive in size and the overall trace-fossil diversity is 1 (only Macaronichnus is
present).
Facies 5 consists of polymictic, clast- (F5a) and matrix-supported (F5b), granule to
medium-pebble conglomerates (Fig. 3.4F). They are dominantly clast-supported with a medium-
to coarse-grained sand matrix (F5a); however, the conglomerate is locally matrix-supported within
beds that have a high mud-matrix component (F5b). The mud-matrix supported conglomerates
commonly overlie the sand clast-supported conglomerates. Clast compositions are dominated by
quartz and lithic fragments. Clasts are sub-rounded to well-rounded. F5 varies in thickness from
0.05–5 m. Bioturbation is mainly absent (BI 0–1) with only firmground Thalassinoides that extend
down from the basal contact of F5 (Fig. 3.4F), and Chondrites, Planolites, and Phycosiphon locally
within the mud matrix-supported F5b conglomerates.
55
Table 3.1: Facies summary
Summary table of lithological, textural, sedimentological, ichnology, reservoir characteristics (permeability and porosity), and interpreted depositional environments for facies identified in the Pembina Oil Field (this study). Sedimentological abbreviations: siltstone (slst), sandstone (sst), shale (sh), hummocky cross-stratification (HCS). Trace fossil abbreviations: Asterosoma (As), Chondrites (Ch), Cylindrichnus (Cy), Diplocraterion (Di), Helminthoida (He), Macaronichnus (Ma), Palaeophycus (Pa), Phycosiphon (Ph), Planolites (Pl), Rhizocorallium (Rh), Rosselia (Ro), Scolicia (Sc), Skolithos (Sk), Teichichnus (Te), Thalassinoides (Th), Trichichnus (Tr), Zoophycos (Zo). Bioturbation index (BI) values based on Reineck (1963) and modified by Taylor and Goldring (1993).
Percent
Sandstone/
Siltstone
Grain Size Sedimentology IchnologyBI
(0–6)
Average
Permeability
(geometric
mean)
Average
Porosity
Depositional
EnvironmentContacts
0–10%shale with up to 10%
vfg sand inter beds
Sst/Slst: discontinuous-, parallel-
and wave-ripple laminated
sand beds. Sh: wavy laminaeCh, He, Pa, Ph,
Pl, Sc, Sk0–3 N/A N/A shelf/ramp
L = gradational;
U = gradational
2a 10–30%shale with up to 30%
slst - fg sst1–3 lower offshore
2b 30–50% shale with up to 50%
slst - fg sst1–6
lower to upper
offshore
2c 50–80% shale with up to 80%
slst - fg sst 2–6 upper offshore
50–100%
fg sandstone with up
to 50% shale inter
beds
Sst/Slst: HCS, wave-, inclined
parallel-, combined flow- and
current-ripple laminated
sandstones. Sh: wavy laminae
and beds
As, Ch, Cy, Di,
Ph, Pl, Sk, Te, Th,
Tr, Zo
0–3
lower delta front
(lower shoreface
equivalent)
L = gradational,
erosional, FS; U
= gradational,
erosional
95–100% vfg - fg
Sst/Slst: HCS, wave ripple,
inclined parallel, combined
flow and current ripple
laminated sandstones. Sh:
wavy laminae
N/A 0–1
lower to upper
delta front
(middle shoreface
equivalent)
L = gradational,
erosional; U =
erosional
5a0–50% sand
matrix
sand matrix with cg
sand to cobble clasts
5b0–50% mud
matrix
mud matrix with cg
sand to cobble clasts
7.30%upper shoreface
to foreshore
L = erosional;
U= sharp,
gradational
L= gradational;
U = gradational,
erosional, FS
Facies
Facies 1: Dark grey- to
black silty mudstone to
shale with very fine-
grained sandstone laminae
Facies 3: Massive to
bioturbated sandstone with
parallel and wavy shale
beds
Facies 4: Apparently
structureless to HCS
sandstone
9.90%
16.40%
Facies 2: Dark grey
bioturbated sandy
mudstone to muddy
sandstone
Sst/Slst: discontinuous-, parallel-
, inclined- and wave-ripple
laminated, mudstone rip-up
clasts, HCS, lenticular bedding.
Sh: wavy laminae
As, Ch, Cy, Di,
Gy, He, Pa, Ph,
Pl, Rh, Ro, Sc, Sk,
Te, Th, Tr, Zo
0.69 mD
18.8 mD
Facies 5: Clast- to
matrix-supported
conglomerate
parallel and inclined laminae Ch, Pl, Ph, Th 0–1 84.4 mD
56
Figure 3.4: Facies core images
Facies photographs. A) Facies 2a: Weakly to moderately bioturbated (BI 1–4) sandy/silty mudstone (30% sand/silt content). Sandstone/siltstone is contained in laterally discontinuous tempestites and in burrow fills. Yellow arrows mark bases of discontinuous tempestites and red arrows mark bases of wavy shale laminae (10-26-047-07W5, 1548.8 m). B) Facies 2b: Moderately to intensely bioturbated (BI 3–5) sandy mudstone (40% total sand content; 03-07-048-08W5, 1647.2 m). C) Facies 2c: Moderately to intensely bioturbated (BI 2–6) muddy sandstone (65% combined siltstone/sandstone content; 03-07-048-08W5, 1652.8 m). D) Facies 3: Sandstone with mm- to cm-scale wave-ripples (15-27-047-07W5, 1525.8 m). E) Facies 4: Carbonaceous detritus-rich HCS sandstone. Mudstone rip-up (MR) clasts are evident towards the bottom of the sample (03-07-048-08W5, 1640.5 m). F) Bioturbated contact between F5a and F4 (yellow dashed line). The base of the F5a conglomerates is erosional. There is a vertical firmground Thalassinoides (Th) that extends from the F4–F5a contact into F4 (15-27-047-07W5, 1522.3 m). Trace fossil abbreviations: Chondrites (Ch), Gyrochorte (Gy), Phycosiphon (Ph), Planolites (Pl), Rosselia (Ro), Schaubcylindrichnus (Sc), Skolithos (Sk), Teichichnus (Te), Thalassinoides (Th), and Trichichnus (Tr).
57
3.3.2. Facies Association One (FA1): Sandying upwards shelf/ramp to upper delta front (middle shoreface equivalent) deposits
Facies association 1 (FA1) includes sanding-upwards successions (F1 – F2a – F2b – F2c
– F3 – F4) that represent normal progradation from a shelf/ramp setting (F1) to an upper delta
front (middle shoreface equivalent) environment (F4; Fig. 3.5), or normal progradation from a
shelf/ramp (F1) to the upper offshore (F2c). Where the entire progradation sequence is complete,
the poorly sorted clast-supported conglomerates of F5a overlie shoreface sandstones of F4.
Internal flooding surfaces often exist separating thinner sanding upward successions F1 – FA2
(a/b/c) below from thicker more complete FA1 successions above (F2a – F2b – F2c – F3 – F4).
Complete FA1 successions that do not contain internal flooding surfaces are rare. FA1 has a
gradational lower contact with the underlying Blackstone Formation and an sharp erosional upper
contact with overlying progradational clast-supported or mud-supported transgressive
conglomeratic deposits (FA2). The contacts between bioturbated facies in FA1 (F1–F2) are
gradational and are characterized by an increase in combined siltstone and sandstone content.
Several allogenic and autogenic surfaces exist within FA1 and it is common for bioturbated facies
with lower sandstone/siltstone content to overlie sandier and siltier units. Additionally, deltaic
deposits may transition to normal shoreface deposits and vice versa as a result of autogenic lobe
switching. The internal flooding surfaces noted above (allogenic surfaces) are locally marked by
scattered coarse sands to pebbles and siderite nodules. As many as five of these allogenic and
autogenic diastems were noted in some cores. The thickness of FA1 ranges from 6 – 13 m.
3.3.3. Facies Association Two (FA2): Transgressive Conglomerate Deposits
F1 and F5 comprise FA2 and were deposited in an upper shoreface to foreshore
environment during transgression and during the later stages of marine progradation. The
transgressive surface of erosion upon which the conglomerates are deposited is highly irregular,
with many steps and lows along its extent (Leggitt et al., 1990). This surface was locally
subaerially exposed during forced regression, and the erosional topography controlled the
distribution and character of the transgressive conglomerates within the Cardium Formation
(Krause et al., 1994; Walker and Eyles, 1991). As a result, the contact between FA2 with FA1 is
irregular and has highly variable vertical relief across the study area. The contacts between mud-
supported (F5b) and sand-supported conglomerates (Fba) are typically gradational and are
marked by an increase in siderite cementation as they grade from sandy to muddy matrices. While
58
no reproducible stacking pattern between sand- and mud-matrix supported conglomerates was
observed, the poorly sorted mud matrix-supported (transgressive) conglomerates often overlie
the (progradational) clast-supported conglomerates (F5a). F1 always gradationally overlies F5
conglomerates and was deposited during the initial and later stages of transgression The
bioturbation intensity is absent to weak (BI 0–1) within F5, and this likely reflects the poor
preservation potential of trace fossils in conglomerates, while the bioturbation intensity is absent
to moderate (BI 0–3) within F1 mudstones (Dashtgard et al., 2008b). The preserved thickness of
F5 is highly variable depending on the proximity to steps or lows along the E5 surface and ranges
from 1 cm – 8 m (Fig. 3.5), while the thickness of FA2 is unknown as cored intervals do not include
the full F1 thickness in any well analyzed
59
Figure 3.5: Core litholog 03-07-048-08W5
Core litholog with gamma-ray and resistivity log profiles for 100/03-07-048-08W5/0 representing the vertical facies changes within the SW part of the study area. The well was chosen because it is one of the best preserved and newest cores logged (RR: 1988-10-07), and it is one of the few that contains all described facies and facies associations. Sandstone grain size is very-fine upper throughout. Bioturbation Index, after Taylor and Goldring (1993), is defined in the legend (Fig. 3.6). Sandstone grain size remains consistent throughout the section (fine upper to fine lower).
60
Figure 3.6: Cardium type log legend
Legend of symbols used for Cardium type log sections.
3.3.4. PDPK
Micropermeability was measured from 758 points across 44 core samples taken from
Facies 2a, 2b, 2c and 3. Annotated core photographs for PDPK analyses of two samples are
shown in Figure 3.7. Individual measurements were taken from one of three permeability
elements: 1) vertical and horizontal silt/sand filled burrows (burrow), 2) sand beds with
preservation of primary stratification (tempestites), and 3) indistinct bioturbated muddy-sandstone
to sandy mudstone lithologies (matrix). Micropermeabilities across the 44 samples range from 1.0
× 10-4 mD to 65.4 mD, with an average of 0.72 mD. The Kgeometric value calculated for each well
61
was then plotted against the range of PDPK measurements taken for samples from the same
well, and by permeability element (e.g., burrow, tempestite, or matrix; Fig. 3.8). Wells with higher
Kgeometric values have higher average PDPK values and a wider range of permeability values. Of
note, below an average Kgeometric of 0.35 mD, all microperm values (n = 237) remain below 0.627
mD, and are not appreciably higher than matrix permeability. For average Kgeometric values between
0.35 mD and 0.65 mD, burrows show permeabilities up to 2.18 mD, which is more than 40 times
greater than the average matrix permeability. However, when the average permeability of F2b
and F2c in a well exceeds 0.6 mD, individual permeability measurements taken from burrows and
tempestites range up to 65.4 mD, which is roughly 730 times higher than the average matrix
permeability.
Figure 3.7: PDPK measurement positions (03-07-048-08W5 & 08-11-049-05W5)
A) Core photograph of F2b (Kgeometric = 0.39 mD) showing the PDPK analysis points and their corresponding permeability values (03-07-048-08W5, 1647.5 m). B) Core photograph of F2b (Kgeometric = 0.95 mD) showing the PDPK analysis points and their corresponding permeability values (08-11-049-05W5, 1269.0 m). All permeability measurements are in millidarcies (mD).
62
Figure 3.8: PDPK versus facies plots
A) Plot comparing Kgeometric for each well against PDPK measurements taken from samples from the same well. Blue represents vertical and horizontal silt/sand filled burrows (burrow), red represents tempestites (tempestite), and grey represents bioturbated matrix (matrix). B) Plot comparing Kgeometric for each well against PDPK matrix measurements only. There is no discernible trend in PDPK matrix permeabilities with increasing facies 2b/2c Kgeometric values.
3.3.5. Reservoir Characterization
Tight-oil plays in the study area are divided into two distinct regions: acreage with
prospective halo-oil and acreage with prospective perm-oil. 1) Halo-oil plays were defined loosely
by Clarkson and Pedersen (2011) as oil production from areas proximal to and immediately
surrounding convention oil reservoirs that do not meet traditional net-pay and petrophysical cut-
offs (average matrix permeability > 0.1 mD). We have revised this definition to include oil
production from areas that are up to 5 km away from the 2.5 m sandstone isopach contour. 2)
63
Perm-oil plays include all horizontal wells that have horizontal-leg midpoints further than 5 km
from the 2.5 m sandstone isopach contour. This distinction is made because of the impact of
conventional oil production (extensive waterflooding from 1953–~1980) on production rates of
recently drilled horizontal wells.
Multiple contour maps including porosity, permeability (Kgeometric), facies thickness,
and combinations of porosity/permeability and facies thicknesses were constructed to compare
reservoir characteristics to horizontal production. Horizontal wells within east-central Pembina are
generally drilled horizontally to the bottom of the economically exploitable bioturbated reservoirs
(~30% combined sandstone/siltstone content), and hydraulically fracked upwards into the
overlying porous and permeable bioturbated subfacies. Qualitative spatial and quantitative
graphical analyses were undertaken to determine which reservoir properties listed above had the
greatest impact on oil production (3rd month daily average production). The reservoir properties
that appear to show the closest correlation to oil production include sandstone facies thicknesses,
and bioturbated facies Kgeometric, and these maps are included herein (Figs. 3.9 – 3.11). The
midpoint between the surface-hole location and location of the terminal fracture-stimulation
position was chosen for plotting the position of horizontal-well production on the maps.
3.3.6. Mapping
The sandstone isopach map shows the thicknesses of facies 3 and 4 (Fig. 3.9). Four isolated and
semi-continuous thick sandstone trends are evident on the map: 1) a globular geobody that
approaches 7 m thick in 050-07W5; 2) a semi-linear geobody that is approximately 6 m thick in
049-05W5; 3) a globular geobody that exceeds 7 m thick in 049-07 / 08W5; and 4) a prominent
linear geobody in the SW corner the study area where the combined F3 / F4 sand thickness
exceeds 8 m (Fig. 3.9). The 0 m sandstone line marks the termination of F3 and F4 deposition.
Of note is the embayed character of the sandstone towards the SE end of the study area, and the
presence of thin sandstones immediately east of the intersection of townships 48 and 49, and
ranges 8 and 9W5. The sandstone isopach map does not extend through the northeast end of
the study area due to the position of the pool edge boundary (Fig 3.9).
64
Figure 3.9: Sandstone (F3, F4) sandstone isopach map
Sandstone (F3, F4) isopach map. Contours were created using advanced kriging methods (anisotropy 1.5, angle 150°) in Surfer® and are based on data from 209 vertical wells in the study area. The midpoint of all horizontal wells drilled in the area are shown with corresponding 3rd month average daily production (m3 /d). The halo-oil play includes all areas of the map that contain contours, and do not fall into either the “effective conventional production (red)” or “perm-oil play” (green) areas. The prominent geobodies identified as 1 to 4 are referred to in the text (see Section 3.3.6). Contour interval is 0.5 m.
65
The bioturbated facies (F2b and F2c) permeability (Kgeometric) contour map is shown in
Figure 3.10. Five isolated and semi-continuous permeability trends are evident on the map: 1) a
narrow NW-SE-oriented trend of low permeability that coincides with the embayment in the east-
central portion of the study area; 2) a more globular permeability low in 047-07 / 08W5 and 048-
07 / 08W5; and 3-5) three globular Kgeometric permeability highs found in the north-east (#3; 048 /
049-04W5), west-central (#4; 049-08 / 07W5), and south-west (#5; 047 / 048 – 09W5) quadrants
of the study area (shown in yellow on Fig. 3.10). In areas 1 and 2, Kgeometric values are as low as
0.11 mD. In areas 3 to 5, Kgeometric values exceed 1.8 mD, 1.7 mD and 1.1 mD, respectively. The
Kgeometric map shows a roughly inverse correlation to the sandstone isopach map in that sandstone
thick generally coincide with low permeability zones in the bioturbated facies.
66
Figure 3.10: Bioturbated facies (F2b, c) permeability map
Contour map of Kgeometric values of bioturbated facies (F2b, c). Contours were created using advanced kriging methods (anisotropy 1.5, angle 150°) in Surfer®, and are based on data from 209 vertical wells in the study area. The midpoint of all horizontal wells drilled in the area are shown with corresponding 3rd month average daily production (m3 /d). Prominent trends in Facies 2b, c permeabilities described in the text are labelled for easy reference (yellow refers to higher permeability areas 3–5). Sandstone geobodies shown in Figure 3.9 are overlain for reference, and highlight areas of conventional production and waterflooding. Contour interval is 0.1 mD.
67
The bioturbated facies (F2b and F2c) thickness contour map is shown in Figure 3.11. Four
discernable thickness trends are evident on the map: 1) a narrow to globular NW-SE-oriented thin that
coincides with the embayment in the east-central portion of the study area; 2) an E-W trending thin in
047-07 / 08W5 that has a combined F2b/F2c thickness less than 6 m; 3) a globular zone of thin
bioturbated facies located in the northwest part of the study area (049-08W5); and 4) an elongate thin
in the northern part of the study area (050-07W5) that is truncated to the east by the approximate pool
edge boundary. The bioturbated facies thickness appears to have exerted limited influence on horizontal
well production within east-central Pembina. Above 7 m isopach thickness there is no discernable
spatial correlation between increasing reservoir thickness and horizontal well production.
68
Figure 3.11: Bioturbated facies (F2b, c) isopach thickness map
Contour map of bioturbated facies (F2b, c) thicknesses. Contours were created using advance kriging methods (anisotropy 1.5, angle 150°) in Surfer®, and are based on data from 209 vertical wells in the study area. The midpoint of all horizontal wells drilled in the area are shown with corresponding 3rd month average daily production (m3 /d). The prominent thin geobodies described in the text are labelled 1 to 5 and yellow fill highlights areas of thicker bioturbated facies. Sandstone geobodies shown in Figure 3.9 are overlain for reference and indicate areas of conventional production and waterflooding. Contour interval is 0.5 m.
69
3.4. Reservoir Controls on Production
3.4.1. PDPK
Analysis of PDPK data indicates that sandstone-filled burrows and horizontally laminated
sandstone beds (tempestites) are the most permeable components of the bioturbated reservoir
facies (Fig. 3.8), and that the sandstones beds and sandstone-filled burrows likely serve as the
primary flow pathways for hydrocarbons. Matrix permeability is negligible throughout facies 2b
and 2c (Fig. 3.8B). Bioturbation increases effective permeability when discrete vertical and
horizontal burrows connect highly permeability horizontal beds in dual-permeability systems
(Gingras et al., 1999; La Croix et al., 2013; Pemberton and Gingras, 2005). There is an abrupt
increase in sandstone-filled burrow and tempestite spot permeabilities where the average
bioturbated facies permeability (kgeometric) exceeds 0.35 mD (Fig 3.8). Below this threshold, the
sandstone burrows and tempestites have permeabilities similar to the matrix. A second abrupt
increase in sandstone burrow and tempestite permeabilites occurs where kgeometric exceeds ~ 0.65
mD.
Diagenetic and sedimentological variations that commonly exist across large areas are
likely the main reason why sandstone burrows and tempestites show orders of magnitude
increases in permeability across kgeometric. Cardium Formation conventional sandstone
permeabilities increase updip from the southwest to the northeast across the Pembina-Cardium
pool (MacKenzie, 1975; MacKenzie and Russum, 1976). The decrease in permeability to the
southwest can be attributed to: precipitation of calcareous and/or siderite cements, increased
interstitial clays, or secondary quartz overgrowths within the sandstones (Krause and Nelson,
1984; MacKenzie, 1975). Similar diagenetic alterations likely affected the bioturbated facies in the
southern portion of the study area, causing sandstone burrows and tempestites to have
permeabilities that are an order of magnitude lower than similar features located updip.
3.4.2. Sandstone Isopach
The majority of horizontal wells drilled in east-central Pembina target the fringes of
sandstone isopach thicks (i.e., halo-oil play). These horizontal wells are generally the best
producers. The permeabilities and net-pay thickness (k·h) in the halo-oil play were insufficient to
enable economic exploitation through primary production, and hence these areas remained under
or undeveloped (Nielsen and Porter, 1984; Patterson and Arneson, 1957). Bypassed banked oil
70
commonly accumulates in areas immediately surrounding extensively produced and waterflooded
conventional reservoirs such as the Pembina-Cardium pool (Shepherd, 2009). Qualitative spatial
analysis of Figure 3.9 indicates that much of the primary (unswept) and banked hydrocarbons in
east-central Pembina likely exist on the margins of conventional oil targets within the 0.25 m to
2.5 m sandstone isopach contour; a hypothesis supported by the linear arrangement of the best
oil producers equidistant from sandstone contour lines (e.g., 049-05/06W5, Fig. 3.9).
Consequently, we rank reservoirs that have between 0.25 and 2.5 m of sandstone (Facies 3 and
4) as highly prospective and the most suitable for waterflooding.
Wells drilled immediately below historically effective conventional production targets in
east-central Pembina are generally very poor producers (Fig. 3.9). It is likely that hydrocarbons
immediately underlying conventionally produced reservoir were depleted during extensive
conventional production and waterflooding. Based on this, we hypothesize that oil exploitation
from bioturbated facies below effective conventional production targets (areas 1–4, Fig. 3.9) will
be largely uneconomic.
A third grouping of horizontal wells have been drilled greater than 5 km from the 2.5 m
sandstone isopach contour and are considered to be largely unaffected by conventional oil
production and associated enhanced oil recovery schemes. This part of the Pembina pool is
referred to as a perm-oil play, and includes the majority of the wells drilled in 047-04W5, 048-
05W5, and 048-04W5 (Fig. 3.9). Qualitative spatial analysis of horizontal production data within
this zone does not reveal any discernable trends in relation to sandstone isopach data.
3.4.3. Bioturbated Facies Kgeometric
In east-central Pembina, the Kgeometric of F2b and F2c is the most important control on
production in unconventional light-tight halo-oil and perm-oil plays. This is because the horizontal
wells are drilled into F2b and hydraulically fracked upward into F2c. The importance of bioturbated
facies permeability is best shown when comparing Kgeometric of F2b and F2c to monthly oil
production (m3; Figure 3.12). Permeabilities of bioturbated facies from the wells drilled within the
halo-oil plays (circles, Fig. 3.12) have a clear Gaussian relationship with respect to third-month
oil production, with the lowest production rates coming from areas that have both very low (e.g. <
0.35 mD) and very high (e.g. > 0.85 mD) bioturbated facies (F2b and F2c) Kgeometric. As a result,
an ideal range for future drilling is between 0.35 mD > Kgeometric > 0.85 mD (Figs. 3.12 and 3.13).
For wells that have a bioturbated facies Kgeometric less than 0.35 mD, is it hypothesized that
production is poor because hydrocarbon migration is ineffective owing to limited connectively
71
between sandstone burrows and tempestites. Further, halo-oil play wells that have a bioturbated
facies Kgeometric greater than 0.85 mD have poor production because hydrocarbons were likely
produced during the preceding 55 years of conventional production proximal to the halo-oil play
areas.
There is no definitive relationship between the Kgeometric of F2b and F2c and production
from wells in the perm-oil play. That said, a weak and positive linear relationship does exist
between production and increasing Kgeometric values (Fig. 3.12). However, as previously mentioned
there is a clear contrasting relationship between perm-oil and halo-oil plays shown by Figure 3.12.
Perm-oil play wells have an average F2b, 2c Kgeometric that exceeds that of halo-oil play wells. The
upper limit proposed for wells within the halo-oil play area does not apply to perm-oil play wells.
72
Figure 3.12: Bioturbated facies (F2b, c) versus monthly oil production (horizontal wells)
Kgeometric of bioturbated facies (F2b and F2c) versus monthly oil production (3rd month; m3). The Kgeometric of F2b and F2c at the horizontal wells mid-point were interpolated from Figure 3.10. These values were plotted against the 3rd month total oil production. Circles correspond to horizontal wells drilled within defined halo-oil play areas and below conventional production, and crosses to wells drilled within perm-oil play areas. Sandstone thickness is coloured based on thicknesses 0–2 m, 2–3 m, and > 3 m (F3 and F4 combined thickness). A Gaussian curve best fits the production from halo-oil play wells, and a very poorly defined positive linear relationship fits perm-oil play wells. The area on the graph that encompasses the majority of the halo-oil and perm-oil play wells are coloured blue and green, respectively. The wells drilled within the halo are binned in Figure 3.13 showing the average production for all wells with specific bioturbated facies permeabilities.
73
Figure 3.13: Bioturbated facies permeability versus production bar graph
Bar-graph of halo-oil play wells showing the average production for six binned bioturbated facies permeability groupings (see Fig. 3.12).
3.5. Waterflooding and future exploitation potential in east-central Pembina
Production versus F2b/F2c Kgeometric (Fig. 3.12) reveals the data spread between wells
drilled proximal (<5 km) and distal (>5 km) to previously exploited conventional targets. While the
focus of this study was wells located proximal (<5 km) to sandstone isopach thicks (i.e., halo-oil
play where vertical well spacing was the most dense), analyses uncovered details – or lack thereof
– about perm-oil play wells that were determined to exist near the NW and SE portions of the
study area.
Figure 3.14 highlights the areas that have the optimal reservoir properties for halo-oil play
horizontal production in east-central Pembina. The dark blue areas indicate where the Kgeometric of
bioturbated facies occurs within the optimal range of 0.35–0.85 mD, and the sandstone facies (F3
and F4) thicknesses are between 0.25 m and 2.5 m. Consequently, the dark blue areas that exist
outside of effective conventional production targets are the optimal locations for exploiting light
tight-oil within the halo (red polygons in Fig. 3.12). Where oil production has already commenced,
74
the dark blue areas are the ideal locations for initiating a waterflood in the tight-oil area (as the
bioturbated facies permeabilities are adequate to support efficient horizontal sweep). Secondary
targets include all areas colored light blue (in the optimal range of at least one of the reservoir
properties evaluated) that exist outside of effective conventional production targets within the
halo. Similarly, areas with poor well spacing should be targeted for initial primary horizontal
production, whereas areas with dense well spacing should be targeted for horizontal
waterflooding.
The reservoir controls on production within the perm-oil play in east-central Pembina
was not resolved with the analyses presented in this paper. As a result, no recommendation
for future drilling targets within these zones can be put forward at this time.
75
Figure 3.14: Final waterflood map
Contour map showing the intersection between the ideal range for sandstone (F3, F4) thicknesses (0.25–2.5 m) and bioturbated facies Kgeometric (0.35 mD > Kgeometric > 0.85 mD); these areas are highlighted in dark blue. The dark blue areas are the optimal locations for exploiting light tight-oil and therefore should be targeted for future horizontal production (where there is low horizontal well density, red boxes) and horizontal waterflooding (where there is high horizontal well density). The semi-transparent red blobs correspond to areas of high-density primary and secondary production, and are derived from Figure 3.9.
76
3.6. Conclusions
1. The matrix in east-central Pembina had negligible permeability (<0.6 mD) in all
samples analyzed (Fig. 3.8B).
2. Sandstone burrows and tempestites in the southern portion of the study area
have an order of magnitude lower permeabilities than equivalent deposits to the
northeast. This is likely attributed to diagenetic and sedimentological variation
across the field (downdip = tighter).
3. The best oil production comes from light tight-oil reservoirs with a Kgeometric of F2b
and F2c between 0.35 mD and 0.85 mD (Fig. 3.12), and sandstone (F3 and F4)
isopach thickness between 0.25 m and 2.5 m (Fig. 3.9). These areas form part
of the halo-oil play of the Pembina-Cardium pool.
4. Future horizontal wells drilled within the halo at east-central Pembina should
target zones that fall within the two ideal ranges listed above. Areas with low well
spacing should be target for primary production via horizontal wells and multi-
stage hydraulic fracturing, and areas with high well spacing should be targeted
for horizontal waterflooding.
The data and analyses presented herein provide an in-depth examination of
horizontal production trends which exist in east-central Pembina. While future
development in the basin should never consider one single reservoir property, this paper
shows the clear correlation of sandstone isopach thicknesses and bioturbated facies
permeability with horizontal production.
The methodology employed herein provides a novel way to evaluate reservoirs
which have extensive vertical and horizontal production, and to understand light tight-oil
plays. It is recommended that this methodology by applied to smaller study areas when
making decisions for future well placement due to the geological complexity of subsurface
reservoirs.
77
Chapter 4. Conclusions
Summary
Technological advancements related to horizontal drilling and multi-stage
hydraulic fracturing have resulted in a renewed interest in unconventional, low-
permeability, light-tight oil reservoirs. In particular, these advancements have allowed for
the economic exploitation from the bioturbated lower to upper offshore muddy-sandstones
to sandy-mudstones within the super-giant Pembina oil field. The analyses presented
herein focus on the reservoir characteristics and trends of light-tight oil reservoirs in east-
central Pembina, and also provide information on facies distributions and stratigraphic
architecture. The techniques used can be applied to similar low-permeability fields as a
way to better predict zones that should be targeted for the economic recovery of
hydrocarbons.
Analysis of 38 vertical wells within the study area revealed a total of five facies and
two facies associations. This includes: 1) a silty mudstone (0–10% combined
sandstone/siltstone); 2) bioturbated sandy mudstones to muddy sandstone (10–80%
combined sandstone/siltstone); 3) massive to bioturbated sandstone with mudstone
laminae and beds; 4) HCS sandstone; 5) and a clast to locally matrix-supported
conglomerate. Facies 2 is being targeted in east-central Pembina and therefore was
broken down into three subfacies to highlight ichnological, sedimentological, and
lithological variations present (e.g., 10–30%, 30–50%, and 50–80% combined
sandstone/siltstone). The facies associations were determined to represent sandying
upwards shelf/ramp to upper delta front (middle shoreface equivalent) deposits, and
conglomeratic transgressive deposits.
Core analysis data and formation picks were compiled for 209 wells within east-
central Pembina. These data were used to create contour maps in Surfer® which
highlighted the subsurface changes of selected reservoir properties. This includes
porosities, permeabilities, facies thicknesses, as well as select combinations of these
three reservoir properties (e.g., facies thickness (m) * porosity (ɸ). Once contoured maps
were finalized, horizontal well mid-point positions were overlain. Spatial analysis of trends
were conducted in order to determine the reservoir properties that had some degree of
control on horizontal well production within east-central Pembina. Once this was
completed, quantitative analysis was used in order to confirm or deny suspected reservoir
78
controls on production. The precise value of the reservoir property at the horizontal well
mid-point was interpolated within the contouring software; which was determined to be
representative of the entire horizontal well distance. This value was then graphically
compared to set production intervals for that well (e.g., 1-month, 3-month, 6-month). Using
the analysis presented above, it was determined that the most dominant controls on
production were the sandstone facies isopach thickness (and therefore the proximity to
conventional sandstone targets) and the permeability (Kgeometric) of the bioturbated facies
(30–80% combined sandstone/siltstone exclusively) of which the optimal ranges were
0.25 m to 2.5 m and 0.35 mD to 0.85 mD respectively.
Reservoir evaluations similar to the one presented in this thesis can be conducted
on other reservoirs as a way to improve the understanding of production trends and results
from horizontal wells. The work order undertaken in this study that could potentially be
applied elsewhere includes the following steps: 1) facies analysis should be completed on
a minimum of four equally spaced vertical wells within a single township (100 km2 area).
2) To supplement logged intervals, a minimum of sixteen additional wells per township,
with well-logs and preferably with core analysis data, should be analyzed. 3) Contour
maps should be created which show the distribution of facies dependent core analysis
data (e.g., porosity, permeability). 4) Available horizontal well midpoints should be plotted
onto contour maps and reservoir data interpolated. 5) Interpolated reservoir data should
then be plotted against available production data in order to deduce the reservoir
properties and facies that have an impact on production from horizontal wells. Future wells
drilled should adhere to significant reservoir trends deduced from the above analysis.
The contribution to petroleum geoscience that this thesis makes is that it
represents a new and unique way to evaluate large scale subsurface reservoir trends
within fields that contain historical vertical well and core analysis data, as well as newly
drilled horizontal well production data.
4.1 Study limitations and future work
Limitations and potential sources of error related to the methodology and data
availability existed during the undertaking of this study. This includes, but is not limited to:
1) errors related to facies well picks, specifically within older wells where only vintage E
logs, micrologs and SP logs were available. 2) Contouring limitations related to imperfect
well spacing within the study area (wells analyzed were chosen based on availability and
79
quality of core, core analysis, and well log profiles). 3) Limitations related to PDPK data,
which only allowed for the analysis of unique features that were greater than 0.4 cm in
diameter (burrows that were smaller than this were not measured). Similarly, horizontal
and vertical burrows were not analyzed separately which limits the analysis of horizontal
versus vertical permeability. 4) An arbitrary distance value of 5 km from conventional
sandstone reservoirs, representing the distinction between halo-oil and perm-oil plays,
and this break is only loosely based on quantified data. As a result it likely does not
represent the definitive boundary between areas that are affected by extensive
conventional oil production within east-central Pembina.
Future work should focus on improving on some of the limitations and potential
sources of error listed above. Additionally, the dataset used can be refined in order to
provide recommendations for future horizontal wells drilled within east-central Pembina. It
is recommended that the methodology presented in this thesis be applied to a smaller
study area (< 400 km2). Within a smaller study area, the well spacing should be decreased
which will allow for a better representation (higher resolution) of how reservoir properties
change in the subsurface. It is also recommended that future work improve on our
understanding of horizontal and vertical changes in reservoir properties. As well,
parasequences located between laterally continuous discontinuities should be evaluated
individually, instead of being grouped into a single unit. Figure 3.5 highlights a well that
has at least one stratigraphically significant surface (located within Facies 2) that likely
has implications on horizontal wells drilled proximal to that boundary. Furthermore,
additional stratigraphic work should be completed on determining the nature of surfaces
(allogenic versus autogenic) as well as the degree of deltaic influence across the study
area (based on the percentage of discrete mudstone laminae and beds).
80
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Appendices
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Appendix A: AppleCore Well Logs
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Appendix B: Well Compilation Data
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100/06-22-047-05W5/0 12-26-1989 890.4 1427.0 1444.0 657266.1 5882131.6
100/06-29-047-05W5/0 1-4-1964 894.9 1442.6 1459.4 654094.29 5883818.68
100/14-33-047-05W5/0 2-13-1965 864.4 1392.9 1402.1 655644.3 5886283.2
100/10-35-047-05W5/0 6-7-1963 846.4 1351.8 1370.1 659332.67 5885999.70
100/06-20-047-06W5/0 10-13-1961 882.4 1504.2 1516.4 644318.1 5881880.9
100/06-28-047-06W5/0 7-26-1966 865.0 1468.5 1485.3 645925.5 5883563.4
100/04-29-047-06W5/0 1-11-1963 876.0 1498.4 1513.6 643900.2 5883094.5
100/16-29-047-06W5/0 8-24-1962 862.0 1473.7 1484.4 645073.3 5884337.8
100/08-30-047-06W5/0 2-18-1970 879.3 1494.4 1512.1 643440.5 5883482.4
100/04-19-047-07W5/0 6-15-1956 781.2 1463.7 1479.2 632506.3 5881185.2
100/12-22-047-07W5/0 5-11-1956 886.7 1533.1 1551.4 637385.9 5882079.2
100/06-24-047-07W5/0 8-7-1956 912.0 1548.4 1583.4 641072.4 5881783
100/10-26-047-07W5/0 5-29-1955 902.2 1536.8 1555.4 639784.3 5883777.7
100/15-27-047-07W5/0 10-14-1988 881.5 1515.0 1537.8 638136.3 5884119.6
100/04-29-047-07W5/0 3-2-1956 773.3 1429.8 1447.2 634044.4 5882808.3
100/02-31-047-07W5/0 2-7-1955 801.9 1457.9 1477.7 633187.5 5884382.4
100/10-34-047-07W5/0 9-9-1955 863.8 1492.9 1511.2 638071.3 5885353.3
100/12-35-047-07W5/0 10-16-1955 876.3 1503.9 1520.0 638928.6 5885362.4
100/08-36-047-07W5/0 7-29-1958 890.0 1506.6 1524.9 641784.7 5885042.2
100/02-22-047-08W5/0 3-1-1956 783.3 1518.2 1536.5 628441.6 5880988.5
100/06-24-047-08W5/0 5-23-1956 773.9 1470.7 1484.4 631265.63 5881505.35
100/04-26-047-08W5/0 1-8-1956 855.0 1550.5 1573.7 629202.9 5882675.4
100/12-26-047-08W5/0 2-13-1956 858.3 1556.0 1577.0 629181.6 5883479.6
100/04-32-047-08W5/0 12-5-1954 901.9 1619.1 1646.5 624246.1 5884153.7
100/10-35-047-08W5/0 12-17-1954 913.8 1596.5 1620.9 629943.6 5885110.1
100/12-35-047-08W5/0 2-9-1955 889.1 1582.2 1606.6 629139.7 5885087.6
100/02-26-047-09W5/0 5-31-1955 892.5 1648.1 1663.9 620219.5 5882444
100/16-35-047-09W5/0 11-19-1954 917.4 1668.5 1688.3 620549.9 5885267.1
100/10-36-047-09W5/0 9-18-1955 937.9 1670.9 1689.2 621790.4 5884894.7
100/12-36-047-09W5/0 1-24-1955 929.9 1663.9 1693.5 621002.9 5884875.6
100/14-16-048-04W5/0 10-18-1956 850.7 1303.3 1318.3 665226.7 5891487.1
100/16-20-048-04W5/0 5-8-1958 851.9 1309.1 1325.3 664394.7 5893003.7
100/06-21-048-04W5/0 9-4-1957 850.4 1351.5 1374.3 665289.5 5892332.5
100/08-28-048-04W5/0 2-10-1957 858.0 1300.0 1327.7 665993.7 5893929
100/14-29-048-04W5/0 8-7-1957 841.6 1290.5 1318.6 663533.9 5894647.4
100/08-30-048-04W5/0 8-25-1957 837.9 1298.5 1316.7 662738.3 5893815.6
100/08-31-048-04W5/0 6-13-1957 831.2 1286.9 1305.2 662635.41 5895452.21
UWI
Rig
Release
Date
KB
Elevation
(m)
Upper
Depth
(m)
Lower
Depth
(m)
UTM
EASTING
(X)
UTM
NORTHING
(Y)
130
100/14-05-048-05W5/0 2-12-1960 864.1 1402.1 1417.3 653957.2 5887853.7
100/16-07-048-05W5/0 6-19-1958 859.8 1389.9 1399.6 653105.3 5889466.8
100/06-17-048-05W5/0 12-5-1982 847.7 1367.2 1379.0 653961.3 5890433.3
100/06-25-048-05W5/0 11-15-1959 815.9 1290.8 1307.3 660316.2 5893764.7
100/14-25-048-05W5/0 10-15-1959 816.6 1292.4 1305.5 660304.8 5894584.3
100/06-26-048-05W5/0 8-20-1962 784.3 1263.4 1278.6 658717.57 5893695.26
100/12-31-048-05W5/0 8-3-1979 802.5 1322.0 1340.0 651796.7 5895593.2
100/06-32-048-05W5/0 11-5-1978 837.0 1341.3 1359.5 653549.67 5895051.48
100/16-33-048-05W5/0 12-27-1962 811.1 1295.4 1310.6 656173 5896014.7
100/08-08-048-06W5/0 5-30-1970 856.5 1443.2 1461.5 644955.27 5888384.32
100/06-11-048-06W5/0 11-5-1962 855.0 1409.7 1428.0 649038.81 5888551.93
100/14-11-048-06W5/0 1-11-1960 847.3 1400.3 1414.3 649019.3 5889310
100/16-12-048-06W5/0 12-20-1958 864.7 1400.3 1413.1 651449.5 5889385.4
100/14-18-048-06W5/0 6-27-1955 865.0 1445.7 1467.6 642442.2 5890737.4
100/06-22-048-06W5/0 3-16-1960 830.0 1382.9 1398.1 647307 5891694.4
100/16-22-048-06W5/0 11-7-1960 825.4 1370.4 1388.7 648038.8 5892520.3
100/06-23-048-06W5/0 2-25-1960 833.3 1376.2 1396.0 648950.9 5891743.1
100/16-23-048-06W5/0 12-4-1960 825.1 1367.0 1382.3 649715.4 5892601.4
100/08-24-048-06W5/0 1-23-1960 847.0 1380.1 1389.9 651372.7 5891817.1
100/06-25-048-06W5/0 12-4-1982 813.5 1348.0 1362.0 650366.3 5893309.7
100/08-26-048-06W5/0 7-19-1960 815.6 1355.8 1367.6 649689.5 5893425.7
100/04-27-048-06W5/0 1-15-1970 808.0 1358.2 1370.7 646809.3 5892906.9
100/12-27-048-06W5/0 1-27-1970 824.2 1368.6 1380.7 646845.2 5893706.1
100/16-29-048-06W5/0 9-15-1955 848.6 1395.7 1414.3 644733.05 5894050.45
102/12-34-048-06W5/0 11-16-1990 825.8 1367.0 1376.0 646703.4 5895214.2
100/04-35-048-06W5/0 7-20-1979 816.4 1354.2 1371.4 648470.3 5894685.7
100/11-03-048-07W5/0 8-18-1977 840.6 1457.6 1475.8 637723 5887006.6
100/14-04-048-07W5/0 2-5-1955 765.4 1386.8 1406.4 636011.8 5887326.4
100/12-05-048-07W5/0 5-15-1955 838.5 1472.5 1491.7 633989.7 5886870.9
100/10-06-048-07W5/0 6-20-1955 871.4 1516.1 1535.0 633158.1 5886840.4
100/10-07-048-07W5/0 10-27-1955 857.4 1498.7 1518.2 633127.40 5888448.30
100/11-07-048-07W5/0 7-28-1984 874.3 1514.0 1530.3 632721.3 5888270.8
100/02-08-048-07W5/0 11-18-1955 766.6 1389.3 1415.8 634824.3 5887697.8
100/11-10-048-07W5/0 8-22-1969 826.9 1441.7 1460.0 637460.8 5888680.7
100/16-12-048-07W5/0 3-18-1958 871.1 1469.1 1483.8 641666.2 5889082.9
100/16-13-048-07W5/0 2-20-1958 872.0 1459.1 1474.6 641617.8 5890711.9
100/12-14-048-07W5/0 7-21-1955 819.3 1419.8 1436.5 638745.6 5890247.8
100/16-15-048-07W5/0 3-23-1955 817.8 1418.8 1438.1 638360.87 5890624.25
100/14-18-048-07W5/0 5-5-1956 842.8 1468.2 1489.6 632663.2 5890462.8
100/06-19-048-07W5/0 3-6-1956 858.3 1481.3 1499.6 632642.1 5891267.3
100/14-23-048-07W5/0 3-16-1956 812.6 1403.0 1419.2 639138.7 5892251.5
131
100/08-24-048-07W5/0 3-21-1959 872.0 1453.9 1469.1 641594.1 5891516.4
100/16-25-048-07W5/0 6-11-1957 830.9 1392.3 1408.8 641526.2 5893900.9
100/13-26-048-07W5/0 7-1-1988 813.3 1396.0 1414.0 638719.4 5893864.7
100/04-27-048-07W5/0 8-4-1955 754.4 1353.6 1373.1 637091.2 5892618.9
100/14-28-048-07W5/0 11-15-1956 838.2 1432.6 1450.5 635806.5 5893814.2
100/02-29-048-07W5/0 5-21-1956 834.2 1439.9 1459.4 634644.9 5892552.8
100/08-32-048-07W5/0 12-12-1955 845.5 1429.2 1456.0 634990 5894571.5
100/10-32-048-07W5/0 2-2-1956 847.3 1438.7 1456.9 634576.4 5894954.8
100/14-33-048-07W5/0 11-12-1956 836.4 1422.5 1440.8 635791.1 5895392
100/10-02-048-08W5/0 6-13-1955 889.1 1557.5 1578.6 629873.6 5886738.2
100/04-05-048-08W5/0 1-10-1955 908.6 1620.9 1644.1 624224.8 5885782.9
100/03-07-048-08W5/0 10-27-1988 924.5 1635.0 1655.7 622955 5887400.1
100/11-09-048-08W5/0 9-29-1988 932.5 1614.0 1638.8 626199.4 5888248
102/12-09-048-08W5/0 12-1-1953 931.8 1620.6 1642.6 625805.1 5888229
100/02-11-048-08W5/0 3-20-1955 888.2 1548.7 1568.2 629886.2 5887543.8
100/04-11-048-08W5/0 8-16-1955 892.8 1557.2 1587.7 629086.74 5887522.16
100/02-12-048-08W5/0 7-10-1955 881.5 1530.1 1553.3 631509.2 5887587.3
100/10-13-048-08W5/0 1-23-1956 846.7 1484.4 1502.7 631447.5 5890019.6
100/10-14-048-08W5/0 1-7-1955 869.3 1516.7 1533.8 629821.1 5889976.1
100/02-15-048-08W5/0 2-5-1955 895.2 1562.7 1584.1 628218.7 5889127.5
100/02-16-048-08W5/0 9-18-1955 915.3 1591.1 1609.3 626580.5 5889083.1
100/06-21-048-08W5/0 7-1-1954 902.5 1578.3 1595.3 626123.9 5891083.9
100/08-24-048-08W5/0 12-23-1955 844.0 1467.6 1492.0 631817.8 5891236.8
100/10-27-048-08W5/0 10-27-1955 867.5 1515.5 1533.8 628106.6 5893169.3
100/06-29-048-08W5/0 12-12-1966 888.8 1561.8 1577.0 624442.09 5892730.15
100/08-31-048-08W5/0 12-23-1963 886.4 1554.5 1566.1 623627.6 5894299.9
100/04-33-048-08W5/0 10-27-1964 885.7 1539.5 1555.7 625614.3 5893877.8
100/12-34-048-08W5/0 10-24-1956 883.3 1505.1 1538.6 627256.94 5894756.6
100/02-35-048-08W5/0 8-24-1955 870.2 1500.2 1519.1 629712.1 5894017.8
100/16-36-048-08W5/0 2-16-1956 861.7 1467.6 1485.9 631711 5895276.9
100/11-01-048-09W5/0 1-6-1988 911.6 1639.0 1656.6 621338.9 5886516.3
100/10-03-048-09W5/0 2-27-1956 894.6 1645.3 1669.7 618480.7 5886444.6
100/12-12-048-09W5/0 2-8-1955 892.1 1610.9 1637.4 620896.8 5888113.9
100/07-13-048-09W5/0 7-27-1974 899.2 1606.3 1624.6 621654.5 5889358.4
102/06-15-048-09W5/0 8-21-1981 866.6 1603.0 1621.2 618132.3 5889399.6
100/10-22-048-09W5/0 11-27-1955 856.5 1568.2 1587.4 618361.3 5891289.8
100/02-24-048-09W5/0 2-17-1956 898.9 1602.6 1620.9 621648.4 5890515.1
100/16-24-048-09W5/0 3-23-1956 899.5 1596.9 1614.2 622018.3 5891750.6
100/02-25-048-09W5/0 5-3-1956 905.6 1601.4 1617.0 621606.3 5892193.8
100/16-26-048-09W5/0 2-10-1958 878.4 1570.3 1592.0 620345.9 5893385.7
132
100/06-34-048-09W5/0 7-31-1958 865.3 1572.8 1593.5 617938.8 5894161.8
100/06-06-049-04W5/0 8-8-1957 826.0 1263.4 1289.6 661840.3 5897008.4
100/08-18-049-04W5/0 8-5-1957 855.3 1290.8 1306.4 662552.2 5900300.8
100/06-21-049-04W5/0 7-8-1959 838.8 1249.7 1265.2 664910.7 5901988.1
102/08-06-049-05W5/0 12-1-1985 786.7 1296.0 1308.0 652685.1 5896863.4
100/06-08-049-05W5/0 8-4-1960 755.3 1247.2 1265.8 653633.4 5898367.1
100/16-10-049-05W5/0 10-6-1957 804.7 1273.5 1288.7 657664.6 5899298.8
100/08-11-049-05W5/0 9-20-1958 804.7 1257.3 1275.6 659361.52 5898552.25
100/06-16-049-05W5/0 6-6-1959 791.3 1268.0 1281.4 655192.8 5900045
100/14-17-049-05W5/0 10-28-1959 787.3 1263.4 1278.6 653539.4 5900794.7
100/06-18-049-05W5/0 10-10-1959 774.5 1251.2 1272.8 651939.9 5899940.5
100/02-19-049-05W5/0 1-22-1986 784.8 1261.0 1278.5 652272 5901197.2
100/16-19-049-05W5/0 6-29-1961 760.8 1230.2 1245.4 652621.7 5902333.7
100/06-22-049-05W5/0 11-28-1985 787.6 1246.0 1255.0 656613.5 5901526.5
100/08-01-049-06W5/0 5-24-1981 797.3 1313.0 1331.0 651055.3 5896501
100/08-05-049-06W5/0 2-11-1985 850.8 1386.0 1404.0 644707 5896488.5
100/02-07-049-06W5/0 10-3-1967 824.2 1369.5 1386.5 642581.7 5897550.4
100/08-11-049-06W5/0 3-28-1982 789.5 1298.0 1316.0 649389.9 5898070.6
100/16-13-049-06W5/0 7-5-1959 786.4 1264.9 1280.2 651090.3 5900718.3
100/06-14-049-06W5/0 9-30-1959 794.3 1291.1 1309.4 648689.5 5899830.2
100/10-17-049-06W5/0 7-11-1985 828.5 1352.5 1370.3 644258.13 5900173.43
100/08-19-049-06W5/0 11-8-1982 801.9 1327.0 1340.6 643017.24 5901407.06
100/08-23-049-06W5/0 5-26-1959 775.4 1257.6 1272.8 649439.19 5901468.12
100/06-24-049-06W5/0 8-12-1959 775.1 1249.7 1268.0 650219.4 5901448.2
100/02-28-049-06W5/0 12-18-1984 835.5 1340.0 1352.8 645817.8 5902503.7
100/06-28-049-06W5/0 9-16-1960 828.4 1326.8 1345.1 645333.4 5902972.6
100/08-29-049-06W5/0 11-28-1957 817.2 1323.1 1340.8 644508.93 5902951.81
100/12-29-049-06W5/0 12-21-1987 804.3 1314.0 1332.9 643310.3 5903241.4
100/10-30-049-06W5/0 11-17-1984 777.0 1289.5 1307.5 642542 5903220.3
100/06-35-049-06W5/0 10-21-1960 825.1 1293.9 1318.3 648536.72 5904680.10
100/10-03-049-07W5/0 2-4-1956 747.4 1314.3 1333.8 637780.7 5896672.9
100/10-04-049-07W5/0 7-12-1955 872.0 1445.4 1466.7 636156.8 5896626
100/04-05-049-07W5/0 11-27-1955 837.0 1428.3 1452.7 633735.5 5895755.4
100/11-05-049-07W5/0 6-17-1988 844.1 1429.0 1447.0 634127.6 5896571.1
100/04-06-049-07W5/0 9-2-1956 846.7 1444.1 1462.4 632121.8 5895710.7
100/16-08-049-07W5/0 7-12-1954 872.3 1445.7 1470.1 634879.3 5898603
100/06-11-049-07W5/0 3-3-1957 802.5 1354.2 1377.1 638972.81 5897867.78
100/06-16-049-07W5/0 9-29-1954 849.2 1415.8 1442.6 635681.6 5899449.4
100/13-19-049-07W5/0 8-5-1988 889.5 1454.5 1471.3 631954.7 5901758.8
100/02-22-049-07W5/0 2-26-1956 817.8 1368.6 1386.8 637661.7 5900712.8
133
100/10-26-049-07W5/0 8-10-1961 796.7 1328.0 1346.3 639219.93 5903196.52
100/08-30-049-07W5/0 6-8-1962 868.7 1426.2 1444.5 633128.64 5902624.68
100/16-36-049-07W5/0 11-26-1959 773.0 1274.7 1296.3 641140.6 5905308.5
100/16-03-049-08W5/0 5-4-1956 921.4 1539.9 1560.0 628413.8 5896816.8
100/04-04-049-08W5/0 12-12-1955 877.2 1526.4 1539.9 625605.9 5895537.8
100/16-04-049-08W5/0 7-1-1956 896.1 1527.1 1543.2 626781.3 5896778.1
100/02-05-049-08W5/0 2-6-1956 874.8 1527.7 1541.1 624766.2 5895519.4
100/04-07-049-08W5/0 12-25-1956 875.1 1533.5 1548.7 622310.1 5897063.4
100/14-09-049-08W5/0 7-9-1955 903.4 1530.1 1545.3 625934.5 5898366.5
100/10-10-049-08W5/0 7-15-1956 921.7 1531.9 1549.9 627979.3 5898014.8
102/04-11-049-08W5/0 12-19-2007 922.5 1533.8 1559.5 628742.8 5897322.1
100/06-13-049-08W5/0 6-17-1956 872.9 1458.5 1474.6 630791.2 5899315.5
102/04-15-049-08W5/0 6-11-1989 941.3 1556.0 1577.3 627198.2 5898835.8
100/02-16-049-08W5/0 10-31-1954 928.1 1548.4 1563.6 626324.2 5898798.9
100/08-17-049-08W5/0 7-16-1956 890.3 1518.8 1533.5 625088.8 5899169.8
100/12-18-049-08W5/0 6-24-1957 855.9 1501.1 1515.2 622238.3 5899543.2
100/06-25-049-08W5/0 1-9-1957 894.6 1458.5 1479.8 630705.2 5902552.1
100/06-26-049-08W5/0 11-15-1957 881.2 1463.0 1482.2 629083.9 5902510.7
100/06-27-049-08W5/0 3-6-1956 875.4 1466.1 1484.4 627455.1 5902469.9
100/07-27-049-08W5/0 8-23-1988 876.7 1467.0 1489.5 627855.9 5902510.8
100/06-29-049-08W5/0 12-27-1956 873.3 1487.4 1503.6 624209.00 5902394.77
100/13-34-049-08W5/0 11-14-1988 857.4 1440.0 1458.0 627011 5904875.5
100/14-35-049-08W5/0 11-25-1958 884.8 1450.2 1468.5 629015.8 5904924
100/06-36-049-08W5/0 10-1-1958 877.2 1440.2 1455.1 630662.8 5904160.7
100/02-12-049-09W5/0 10-15-1959 876.9 1540.2 1556.9 621501.9 5897058.5
100/08-24-049-09W5/0 1-13-1958 857.4 1505.1 1517.3 621795.2 5900653.7
100/16-25-049-09W5/0 9-9-1957 851.9 1469.1 1496.6 621691.9 5903118
100/14-34-049-09W5/0 5-8-1958 889.1 1532.8 1547.8 617637.9 5904635.3
100/08-09-050-05W5/0 8-8-1985 746.8 1175.0 1193.2 655754.9 5908190.1
100/06-04-050-06W5/0 11-21-1960 790.0 1277.7 1296.0 645232.85 5906210.98
100/12-04-050-06W5/0 3-26-1978 779.1 1289.0 1305.8 644873.7 5906632.1
100/02-05-050-06W5/0 8-16-1986 800.7 1291.0 1308.8 644010.9 5905762
100/12-06-050-06W5/0 8-3-1960 730.3 1228.3 1243.6 641572.3 5906503.1
100/16-15-050-06W5/0 1-30-1989 716.6 1166.0 1183.6 647533.34 5910265.44
100/06-01-050-07W5/0 7-12-1959 783.3 1287.8 1303.0 640361.6 5906065.3
100/08-02-050-07W5/0 8-29-1959 792.5 1301.5 1316.7 639540.9 5906041.5
100/16-03-050-07W5/0 1-29-1960 816.3 1320.1 1346.0 637892.53 5906799.75
100/16-04-050-07W5/0 9-7-1959 804.1 1319.2 1339.6 636269 5906752.7
100/16-05-050-07W5/0 9-21-1959 823.3 1350.6 1367.3 634645.1 5906706.4
100/16-09-050-07W5/0 1-16-1960 823.3 1328.9 1347.8 636223.2 5908359.4
134
100/16-10-050-07W5/0 1-31-1960 849.8 1350.3 1373.1 637846.9 5908454.2
100/06-12-050-07W5/0 11-12-1960 783.0 1282.6 1300.0 640314.6 5907673.6
100/06-14-050-07W5/0 12-4-1961 828.1 1332.6 1346.0 638649.4 5909256.4
100/16-17-050-07W5/0 6-11-1959 830.3 1343.9 1362.2 634555.1 5909944.4
100/16-04-050-08W5/0 3-4-1960 851.6 1426.2 1441.4 626535.6 5906487.6
100/14-13-050-08W5/0 3-29-1960 839.4 1375.0 1396.6 630515.7 5909781.8
100/16-14-050-08W5/0 8-9-1960 842.5 1378.9 1397.2 629665.8 5909805.3
100/02-03-050-09W5/0 1-5-1987 889.7 1532.0 1545.3 617931 5905016.6
100/08-04-050-09W5/0 12-17-1958 890.9 1539.2 1555.1 616792.3 5905440.9
102/06-15-050-09W5/0 11-1-1982 855.7 1476.0 1494.2 617594.9 5908865.2
100/10-15-050-09W5/0 9-1-1984 857.1 1473.0 1491.8 617883 5909179.7
135
Geo
mean
(mD)
Thickness
(m)Phi (%) Phi-h
Geo
mean
(mD)
Thickness
(m)Phi (%) Phi-h
Geo
mean
(mD)
Thickness
(m)Phi (%) Phi-h
100/06-22-047-05W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.48 9.28 0.075 0.69
100/06-29-047-05W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 9.00 0.00
100/14-33-047-05W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.41 10.11 0.121 1.22
100/10-35-047-05W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 7.25 0.00
100/06-20-047-06W5/0 0.22 0.062 0.01 0.00 0.00 0.000 0.00 0.42 11.64 0.142 1.65
100/06-28-047-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 12.40 0.00
100/04-29-047-06W5/0 7.28 1.86 0.060 0.11 0.00 0.00 0.000 0.00 0.41 10.94 0.132 1.45
100/16-29-047-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.34 10.44 0.100 1.04
100/08-30-047-06W5/0 16.60 0.61 0.088 0.05 0.00 0.00 0.000 0.00 0.53 10.14 0.130 1.32
100/04-19-047-07W5/0 0.00 0.00 0.000 0.00 10.02 4.64 0.119 0.55 0.30 12.57 0.070 0.89
100/12-22-047-07W5/0 0.27 0.031 0.01 21.84 4.24 0.160 0.68 0.79 13.17 0.125 1.65
100/06-24-047-07W5/0 4.35 1.37 0.100 0.14 6.02 4.06 0.152 0.62 0.82 13.10 0.095 1.25
100/10-26-047-07W5/0 90.62 1.46 0.061 0.09 33.38 2.40 0.198 0.48 0.31 10.25 0.105 1.07
100/15-27-047-07W5/0 4.06 1.05 0.060 0.06 3.20 4.61 0.149 0.69 0.29 8.07 0.088 0.71
100/04-29-047-07W5/0 0.36 1.49 0.057 0.08 3.09 5.64 0.124 0.70 0.35 7.56 0.059 0.44
100/02-31-047-07W5/0 0.74 1.95 0.044 0.09 14.19 8.84 0.162 1.43 0.12 8.35 0.093 0.77
100/10-34-047-07W5/0 5.23 1.98 0.070 0.14 4.26 5.15 0.161 0.83 9.20 0.078 0.72
100/12-35-047-07W5/0 12.52 1.65 0.046 0.08 4.85 1.89 0.142 0.27 0.38 9.05 0.094 0.85
100/08-36-047-07W5/0 3.09 0.55 0.091 0.05 15.80 2.29 0.136 0.31 12.06 0.076 0.91
100/02-22-047-08W5/0 0.00 0.00 0.000 0.00 7.91 6.89 0.121 0.83 0.31 9.54 0.049 0.46
100/06-24-047-08W5/0 0.00 0.00 0.000 0.00 8.63 4.42 0.151 0.67 0.23 10.92 0.050 0.54
100/04-26-047-08W5/0 1.25 1.22 0.018 0.02 12.45 5.28 0.130 0.69 0.23 8.77 0.057 0.50
100/12-26-047-08W5/0 0.90 0.79 0.053 0.04 11.37 4.27 0.138 0.59 0.33 9.84 0.054 0.53
100/04-32-047-08W5/0 0.58 0.051 0.03 7.04 7.31 0.191 1.40 0.50 9.79 0.109 1.06
100/10-35-047-08W5/0 1.00 0.70 0.086 0.06 14.65 5.80 0.147 0.85 0.22 9.78 0.049 0.48
100/12-35-047-08W5/0 0.49 0.067 0.03 9.34 6.04 0.155 0.94 0.52 10.21 0.054 0.55
100/02-26-047-09W5/0 5.17 2.20 0.065 0.14 7.08 5.21 0.160 0.83 9.96 0.117 1.17
100/16-35-047-09W5/0 0.40 0.036 0.01 5.38 7.22 0.139 1.00 0.89 11.58 0.088 1.02
100/10-36-047-09W5/0 1.44 2.96 0.024 0.07 8.59 5.52 0.126 0.69 1.12 11.55 0.078 0.90
100/12-36-047-09W5/0 0.00 0.00 0.000 0.00 4.48 6.44 0.123 0.79 1.10 10.84 0.095 1.03
100/14-16-048-04W5/0 0.00 0.00 0.000 0.00 0.00 1.05 0.000 0.00 0.76 12.76 0.071 0.91
100/16-20-048-04W5/0 0.00 0.00 0.000 0.00 0.00 1.05 0.000 0.00 1.05 13.49 0.111 1.50
100/06-21-048-04W5/0 0.00 0.00 0.000 0.00 0.00 0.000 0.00 1.71 11.25 0.090 1.01
100/08-28-048-04W5/0 1.53 1.04 0.065 0.07 0.00 1.20 0.000 0.00 1.74 13.29 0.091 1.20
100/14-29-048-04W5/0 0.09 0.131 0.01 0.00 0.70 0.000 0.00 1.21 13.81 0.087 1.20
100/08-30-048-04W5/0 0.00 0.00 0.000 0.00 0.00 1.05 0.000 0.00 1.64 11.64 0.077 0.89
100/08-31-048-04W5/0 0.00 0.00 0.000 0.00 0.00 1.05 0.000 0.00 12.00 0.00
100/14-05-048-05W5/0 0.52 0.106 0.06 0.00 0.00 0.000 0.00 0.61 10.33 0.108 1.12
100/16-07-048-05W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.97 10.24 0.083 0.85
100/06-17-048-05W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.11 8.57 0.072 0.62
100/06-25-048-05W5/0 0.51 0.022 0.01 0.00 0.00 0.000 0.00 1.23 11.95 0.098 1.17
100/14-25-048-05W5/0 0.00 0.00 0.000 0.00 0.00 0.31 0.155 0.05 1.56 10.65 0.095 1.02
100/06-26-048-05W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.6 12.25 0.00
100/12-31-048-05W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.28 8.07 0.067 0.54
100/06-32-048-05W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 10.10 0.00
100/16-33-048-05W5/0 0.00 0.00 0.000 0.00 3.11 1.22 0.164 0.20 0.32 8.20 0.124 1.01
100/08-08-048-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 12.50 0.00
Bioturbated Facies (F2)Conglomerate Facies (F5) Sandstone Facies (F3/F4)
UWI
136
100/08-08-048-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 12.50 0.00
100/06-11-048-06W5/0 0.35 0.00 0.00 0.00 0.000 0.00 12.50 0.00
100/14-11-048-06W5/0 0.37 0.078 0.03 0.00 0.00 0.000 0.00 0.82 12.27 0.118 1.45
100/16-12-048-06W5/0 0.39 0.077 0.03 13.33 1.13 0.160 0.18 0.84 11.57 0.081 0.94
100/14-18-048-06W5/0 0.00 0.00 0.000 0.00 13.27 1.04 0.165 0.17 0.76 11.09 0.078 0.87
100/06-22-048-06W5/0 1.67 0.70 0.00 0.00 0.00 0.000 0.00 0.85 10.97 0.131 1.44
100/16-22-048-06W5/0 0.00 0.00 0.091 0.00 0.00 0.00 0.000 0.00 0.83 10.51 0.102 1.07
100/06-23-048-06W5/0 7.02 1.31 0.069 0.09 0.00 0.00 0.000 0.00 0.72 11.77 0.109 1.29
100/16-23-048-06W5/0 11.88 0.76 0.082 0.06 15.87 1.22 0.214 0.26 0.77 12.01 0.101 1.21
100/08-24-048-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.68 11.31 0.111 1.26
100/06-25-048-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.43 11.39 0.095 1.08
100/08-26-048-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.69 10.98 0.109 1.19
100/04-27-048-06W5/0 8.99 0.52 0.067 0.03 8.46 0.55 0.170 0.09 0.83 10.20 0.136 1.38
100/12-27-048-06W5/0 1.31 0.18 0.109 0.02 15.13 0.74 0.182 0.13 0.77 10.53 0.131 1.38
100/16-29-048-06W5/0 0.50 0.00 1.00 0.00 0.78 12.50 0.00
102/12-34-048-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.47 12.28 0.088 1.09
100/04-35-048-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.17 10.63 0.062 0.66
100/11-03-048-07W5/0 3.68 1.61 0.070 0.11 9.81 4.03 0.171 0.69 0.44 9.25 0.105 0.97
100/14-04-048-07W5/0 0.39 0.092 0.04 14.84 4.42 0.179 0.79 0.59 10.31 0.125 1.29
100/12-05-048-07W5/0 0.48 0.087 0.04 13.11 8.54 0.172 1.47 0.33 8.77 0.085 0.74
100/10-06-048-07W5/0 1.22 1.37 0.060 0.08 26.26 8.59 0.185 1.59 0.37 8.96 0.082 0.74
100/10-07-048-07W5/0 0.75 0.00 4.50 0.00 0.33 12.50 0.00
100/11-07-048-07W5/0 360.75 1.24 0.068 0.08 66.46 6.50 0.138 0.89 0.47 12.48 0.067 0.84
100/02-08-048-07W5/0 0.22 0.051 0.01 10.41 6.79 0.164 1.11 0.36 9.06 0.098 0.89
100/11-10-048-07W5/0 0.92 0.06 0.060 0.00 0.00 0.00 0.000 0.00 0.37 9.75 0.108 1.06
100/16-12-048-07W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.97 10.42 0.074 0.77
100/16-13-048-07W5/0 1.00 0.70 0.064 0.04 22.30 1.58 0.169 0.27 0.87 11.80 0.081 0.96
100/12-14-048-07W5/0 0.00 0.00 0.000 0.00 22.61 2.80 0.214 0.60 0.47 12.53 0.098 1.22
100/16-15-048-07W5/0 0.35 0.00 2.75 0.00 11.00 0.00
100/14-18-048-07W5/0 0.00 0.00 0.000 0.00 14.65 2.98 0.142 0.42 0.71 11.49 0.070 0.81
100/06-19-048-07W5/0 0.28 0.019 0.01 0.00 0.00 0.000 0.00 0.83 12.55 0.070 0.88
100/14-23-048-07W5/0 17.81 0.94 0.054 0.05 14.17 1.40 0.174 0.24 0.53 12.00 0.089 1.07
100/08-24-048-07W5/0 0.61 0.117 0.07 5.32 1.49 0.166 0.25 0.63 11.00 0.095 1.05
100/16-25-048-07W5/0 13.59 0.79 0.100 0.08 17.38 4.73 0.152 0.72 0.76 10.39 0.089 0.92
100/13-26-048-07W5/0 0.13 0.00 7.58 2.71 0.169 0.46 0.77 10.14 0.115 1.17
100/04-27-048-07W5/0 0.58 0.057 0.03 7.25 2.50 0.177 0.44 0.57 9.84 0.110 1.08
100/14-28-048-07W5/0 8.60 0.97 0.060 0.06 15.88 3.66 0.198 0.72 0.60 11.31 0.106 1.20
100/02-29-048-07W5/0 0.85 0.066 0.06 9.39 4.30 0.125 0.54 0.59 11.67 0.055 0.64
100/08-32-048-07W5/0 0.33 0.104 0.03 26.84 3.63 0.159 0.58 0.84 10.27 0.099 1.02
100/10-32-048-07W5/0 0.31 0.063 0.02 20.21 3.81 0.151 0.58 0.68 10.61 0.072 0.77
100/14-33-048-07W5/0 0.00 0.00 0.000 0.00 4.68 5.09 0.166 0.84 0.64 10.45 0.118 1.24
100/10-02-048-08W5/0 0.91 0.047 0.04 11.82 5.83 0.179 1.04 0.21 12.08 0.083 1.01
100/04-05-048-08W5/0 1.34 1.53 0.041 0.06 6.52 4.96 0.136 0.68 0.42 10.88 0.083 0.91
100/03-07-048-08W5/0 23.40 3.02 0.076 0.23 23.40 4.89 0.174 0.85 0.39 10.45 0.078 0.82
100/11-09-048-08W5/0 0.99 0.00 14.92 5.36 0.179 0.96 0.21 9.11 0.071 0.64
102/12-09-048-08W5/0 2.78 3.05 0.077 0.23 12.01 3.23 0.173 0.56 0.62 10.79 0.101 1.09
100/02-11-048-08W5/0 0.00 0.00 0.000 0.00 8.97 9.65 0.163 1.57 0.11 11.65 0.079 0.92
100/04-11-048-08W5/0 1.60 0.00 7.50 0.00 11.00 0.00
100/02-12-048-08W5/0 0.47 0.70 0.022 0.02 22.02 7.19 0.167 1.20 0.14 10.24 0.092 0.94
100/10-13-048-08W5/0 7.41 1.71 0.058 0.10 6.60 0.82 0.127 0.10 0.52 11.40 0.052 0.59
100/10-14-048-08W5/0 32.81 1.07 0.092 0.10 17.05 4.96 0.150 0.74 0.54 9.76 0.087 0.85
100/02-15-048-08W5/0 0.55 0.084 0.05 17.82 7.98 0.163 1.30 0.68 9.76 0.074 0.72
100/02-16-048-08W5/0 0.37 0.096 0.04 20.82 4.78 0.180 0.86 0.40 11.39 0.092 1.05
100/06-21-048-08W5/0 0.61 0.00 9.96 3.29 0.137 0.45 0.58 12.71 0.083 1.05
100/08-24-048-08W5/0 0.58 0.00 27.89 2.47 0.145 0.36 0.79 12.10 0.071 0.86
100/10-27-048-08W5/0 2.38 0.00 3.71 0.97 0.137 0.13 0.49 11.49 0.089 1.03
100/06-29-048-08W5/0 0.63 0.00 0.00 0.00 0.000 0.00 11.50 0.00
137
100/08-31-048-08W5/0 1.75 1.01 0.00 2.43 0.82 0.158 0.13 0.48 11.39 0.116 1.32
100/04-33-048-08W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.48 9.16 0.093 0.85
100/12-34-048-08W5/0 0.00 0.00 0.000 0.00 19.14 4.91 0.172 0.84 0.62 10.91 0.102 1.11
100/02-35-048-08W5/0 0.00 0.00 0.000 0.00 36.86 4.96 0.222 1.10 0.44 10.19 0.102 1.04
100/16-36-048-08W5/0 7.07 1.53 0.079 0.12 54.08 4.60 0.167 0.77 0.52 10.97 0.093 1.02
100/11-01-048-09W5/0 0.00 0.00 0.000 0.00 13.20 6.38 0.137 0.87 10.00 0.118 1.18
100/10-03-048-09W5/0 0.18 0.00 49.15 1.86 0.170 0.32 1.19 12.84 0.085 1.09
100/12-12-048-09W5/0 0.00 0.00 0.000 0.00 9.82 5.76 0.139 0.80 0.45 9.24 0.074 0.68
100/07-13-048-09W5/0 39.50 2.44 0.067 0.16 9.48 5.49 0.185 1.01 12.09 0.00
102/06-15-048-09W5/0 28.32 1.57 0.059 0.09 6.37 4.64 0.129 0.60 1.19 11.91 0.098 1.17
100/10-22-048-09W5/0 1.48 4.42 0.044 0.19 12.67 5.67 0.163 0.93 0.72 11.33 0.064 0.72
100/02-24-048-09W5/0 1.11 0.60 0.029 0.02 14.07 2.90 0.124 0.36 0.51 12.26 0.074 0.91
100/16-24-048-09W5/0 0.87 0.61 0.070 0.04 0.00 0.50 0.000 0.00 0.61 12.98 0.062 0.81
100/02-25-048-09W5/0 0.00 0.00 0.000 0.00 0.00 0.50 0.000 0.00 1.18 13.75 0.086 1.19
100/16-26-048-09W5/0 4.81 0.91 0.048 0.04 0.00 0.50 0.000 0.00 0.35 13.57 0.079 1.07
100/06-34-048-09W5/0 1.26 1.65 0.034 0.06 0.00 0.50 0.000 0.00 0.63 13.02 0.088 1.14
100/06-06-049-04W5/0 0.18 0.00 0.00 0.85 0.000 0.00 1.02 13.38 0.089 1.19
100/08-18-049-04W5/0 0.00 0.00 0.000 0.00 0.00 1.20 0.000 0.00 1.94 11.52 0.118 1.36
100/06-21-049-04W5/0 1.72 0.76 0.00 0.00 0.00 0.000 0.00 0.85 7.16 0.092 0.66
102/08-06-049-05W5/0 1.60 2.23 0.070 0.16 0.00 0.00 0.000 0.00 0.51 9.27 0.100 0.93
100/06-08-049-05W5/0 0.00 0.00 0.000 0.00 11.91 2.22 0.149 0.33 0.53 10.13 0.121 1.23
100/16-10-049-05W5/0 0.77 0.00 2.97 4.42 0.113 0.50 1.08 10.21 0.085 0.87
100/08-11-049-05W5/0 0.15 0.00 0.00 0.00 0.000 0.00 0.95 12.44 0.00
100/06-16-049-05W5/0 8.87 0.64 0.052 0.03 16.20 0.92 0.185 0.17 0.51 11.28 0.107 1.21
100/14-17-049-05W5/0 95.04 0.64 0.083 0.05 10.39 2.44 0.196 0.48 0.53 10.30 0.118 1.22
100/06-18-049-05W5/0 942.00 0.52 0.101 0.05 20.69 3.50 0.194 0.68 0.57 10.09 0.115 1.16
100/02-19-049-05W5/0 0.12 0.00 31.69 0.92 0.189 0.17 0.84 11.88 0.114 1.35
100/16-19-049-05W5/0 8.01 1.51 0.078 0.12 24.68 1.73 0.182 0.31 0.58 11.70 0.122 1.43
100/06-22-049-05W5/0 0.00 0.00 0.000 0.00 37.17 6.50 0.169 1.10 8.30 0.117 0.97
100/08-01-049-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.09 7.54 0.091 0.68
100/08-05-049-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.22 8.53 0.099 0.84
100/02-07-049-06W5/0 0.00 0.00 0.000 0.00 21.35 1.04 0.205 0.21 0.36 9.10 0.117 1.07
100/08-11-049-06W5/0 0.10 0.081 0.01 0.00 0.00 0.000 0.00 0.60 9.65 0.095 0.91
100/16-13-049-06W5/0 251.19 0.46 0.116 0.05 30.34 4.08 0.193 0.79 0.51 9.66 0.121 1.17
100/06-14-049-06W5/0 0.13 0.00 51.35 2.62 0.199 0.52 0.59 9.02 0.113 1.02
100/10-17-049-06W5/0 0.30 0.00 0.00 0.00 0.000 0.00 9.55 0.00
100/08-19-049-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.52 9.00 0.108 0.98
100/08-23-049-06W5/0 4.50 0.00 2.15 0.00 10.25 0.00
100/06-24-049-06W5/0 362.69 2.72 0.126 0.34 70.00 2.56 0.210 0.54 0.53 9.43 0.117 1.10
100/02-28-049-06W5/0 0.30 0.069 0.02 21.04 3.75 0.176 0.66 0.71 10.74 0.122 1.31
100/06-28-049-06W5/0 0.00 0.00 0.000 0.00 37.22 2.75 0.204 0.56 0.91 11.18 0.116 1.30
100/08-29-049-06W5/0 0.30 0.00 0.00 1.00 0.000 0.00 12.45 0.00
100/12-29-049-06W5/0 35.17 0.79 0.137 0.11 0.00 1.50 0.000 0.00 0.48 10.82 0.129 1.40
100/10-30-049-06W5/0 13.98 0.92 0.123 0.11 0.00 0.50 0.000 0.00 0.42 12.67 0.126 1.60
100/06-35-049-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 11.25 0.00
100/10-03-049-07W5/0 25.49 1.95 0.076 0.15 9.31 2.71 0.158 0.43 0.77 9.24 0.099 0.91
100/10-04-049-07W5/0 89.80 4.36 0.083 0.36 10.06 4.05 0.175 0.71 0.56 9.77 0.109 1.06
100/04-05-049-07W5/0 0.17 2.04 0.00 45.85 2.71 0.171 0.46 1.16 11.89 0.076 0.90
100/11-05-049-07W5/0 0.00 0.00 0.000 0.00 18.38 2.52 0.169 0.43 0.78 10.99 0.097 1.07
100/04-06-049-07W5/0 9.29 2.26 0.107 0.24 46.81 4.51 0.210 0.95 0.46 11.06 0.125 1.38
100/16-08-049-07W5/0 0.00 0.00 0.000 0.00 26.37 6.00 0.142 0.85 1.52 11.98 0.094 1.12
100/06-11-049-07W5/0 3.00 0.00 4.23 0.00 10.07 0.00
100/06-16-049-07W5/0 0.00 0.00 0.000 0.00 34.39 5.80 0.158 0.92 1.42 12.49 0.092 1.15
100/13-19-049-07W5/0 0.00 0.00 0.000 0.00 24.08 2.33 0.187 0.44 1.10 10.52 0.112 1.18
100/02-22-049-07W5/0 0.00 0.00 0.000 0.00 5.78 0.82 0.145 0.12 0.68 11.92 0.086 1.02
138
100/10-26-049-07W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.69 12.00 0.00
100/08-30-049-07W5/0 0.00 0.00 0.000 0.00 0.95 0.00 11.20 0.00
100/16-36-049-07W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 1.03 12.01 0.131 1.58
100/16-03-049-08W5/0 0.00 0.00 0.000 0.00 22.73 6.61 0.192 1.27 0.85 9.45 0.113 1.07
100/04-04-049-08W5/0 5.99 0.40 0.061 0.02 19.22 4.48 0.134 0.60 0.73 11.21 0.107 1.19
100/16-04-049-08W5/0 0.00 0.00 0.000 0.00 27.72 6.98 0.203 1.42 0.77 8.60 0.120 1.04
100/02-05-049-08W5/0 0.00 0.00 0.000 0.00 11.60 3.53 0.160 0.56 0.44 10.99 0.102 1.12
100/04-07-049-08W5/0 0.00 0.00 0.000 0.00 18.76 2.44 0.155 0.38 1.28 9.79 0.109 1.07
100/14-09-049-08W5/0 0.00 0.00 0.000 0.00 23.02 7.25 0.160 1.16 1.68 8.62 0.086 0.74
100/10-10-049-08W5/0 41.00 3.75 0.077 0.29 79.80 5.09 0.222 1.13 0.56 8.80 0.117 1.03
102/04-11-049-08W5/0 19.30 2.30 0.00 57.81 6.04 0.221 1.33 0.76 9.04 0.113 1.02
100/06-13-049-08W5/0 0.00 0.00 0.000 0.00 12.83 5.34 0.196 1.05 0.63 8.84 0.121 1.07
102/04-15-049-08W5/0 8.55 0.62 0.050 0.03 44.92 5.41 0.202 1.10 0.66 9.27 0.110 1.02
100/02-16-049-08W5/0 0.00 0.00 0.000 0.00 35.40 6.73 0.165 1.11 1.38 8.39 0.087 0.73
100/08-17-049-08W5/0 0.27 0.94 0.064 0.06 55.86 3.11 0.187 0.58 1.28 8.87 0.123 1.09
100/12-18-049-08W5/0 0.00 0.00 0.000 0.00 6.45 2.89 0.109 0.32 1.14 10.07 0.083 0.84
100/06-25-049-08W5/0 0.00 0.00 0.000 0.00 24.35 2.34 0.185 0.43 1.25 10.74 0.107 1.15
100/06-26-049-08W5/0 0.00 0.00 0.000 0.00 1.70 0.146 0.25 11.16 0.109 1.22
100/06-27-049-08W5/0 0.00 0.00 0.000 0.00 12.25 2.35 0.166 0.39 1.18 9.84 0.117 1.16
100/07-27-049-08W5/0 0.00 0.00 0.000 0.00 26.06 1.42 0.144 0.20 1.52 9.82 0.106 1.04
100/06-29-049-08W5/0 1.17 0.00 1.75 0.00 0.55 11.00 0.00
100/13-34-049-08W5/0 0.00 0.00 0.000 0.00 6.06 2.30 0.137 0.32 11.05 0.122 1.35
100/14-35-049-08W5/0 0.00 0.00 0.000 0.00 53.05 1.74 0.158 0.27 1.84 11.40 0.093 1.06
100/06-36-049-08W5/0 0.00 0.00 0.000 0.00 16.55 2.93 0.134 0.39 1.38 10.06 0.085 0.86
100/02-12-049-09W5/0 0.27 0.061 0.02 2.18 1.10 0.139 0.15 0.99 10.77 0.117 1.26
100/08-24-049-09W5/0 0.00 0.00 0.000 0.00 4.12 2.39 0.125 0.30 0.78 10.79 0.116 1.25
100/16-25-049-09W5/0 1.48 1.62 0.041 0.07 6.52 0.98 0.129 0.13 1.25 10.94 0.103 1.13
100/14-34-049-09W5/0 2.76 1.07 0.078 0.08 34.08 0.76 0.177 0.13 0.88 12.44 0.113 1.41
100/08-09-050-05W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.10 3.93 0.107 0.42
100/06-04-050-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 10.00 0.00
100/12-04-050-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.29 9.36 0.128 1.20
100/02-05-050-06W5/0 2905.60 0.27 0.129 0.03 0.00 0.00 0.000 0.00 0.50 11.00 0.120 1.32
100/12-06-050-06W5/0 155.63 0.67 0.121 0.08 0.00 0.70 0.000 0.00 0.71 11.02 0.133 1.47
100/16-15-050-06W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 7.41 0.00
100/06-01-050-07W5/0 11.47 0.88 0.077 0.07 0.00 1.50 0.000 0.00 0.40 10.70 0.129 1.38
100/08-02-050-07W5/0 0.00 0.00 0.000 0.00 5.11 5.36 0.150 0.81 0.84 7.40 0.124 0.92
100/16-03-050-07W5/0 6.25 0.00 0.00 0.00 0.000 0.00 8.95 0.00
100/16-04-050-07W5/0 150.18 3.81 0.087 0.33 8.40 3.17 0.152 0.48 0.77 6.95 0.121 0.84
100/16-05-050-07W5/0 0.58 0.00 17.41 4.32 0.197 0.85 8.23 0.126 1.04
100/16-09-050-07W5/0 208.80 5.86 0.086 0.51 9.20 6.98 0.185 1.29 0.47 7.65 0.125 0.95
100/16-10-050-07W5/0 26.19 1.92 0.093 0.18 7.92 6.67 0.158 1.06 0.40 8.44 0.120 1.01
100/06-12-050-07W5/0 47.67 2.35 0.084 0.20 3.32 5.37 0.167 0.90 6.28 0.133 0.83
100/06-14-050-07W5/0 1.50 0.00 4.46 2.84 0.157 0.45 8.22 0.127 1.05
100/16-17-050-07W5/0 35.54 1.18 0.092 0.11 10.85 5.58 0.172 0.96 0.29 5.18 0.118 0.61
100/16-04-050-08W5/0 0.42 0.065 0.03 0.00 0.00 0.00 0.00 0.68 10.82 0.130 1.40
100/14-13-050-08W5/0 0.00 0.00 0.000 0.00 20.42 1.01 0.211 0.21 0.59 10.30 0.131 1.35
100/16-14-050-08W5/0 0.00 0.00 0.000 0.00 18.24 1.06 0.202 0.21 0.68 10.36 0.130 1.35
100/02-03-050-09W5/0 3.38 1.15 0.069 0.08 0.00 0.00 0.000 0.00 0.43 10.35 0.116 1.20
100/08-04-050-09W5/0 128.78 2.17 0.104 0.23 0.00 0.00 0.000 0.00 0.57 9.60 0.120 1.15
102/06-15-050-09W5/0 0.00 0.00 0.000 0.00 0.00 0.00 0.000 0.00 0.15 8.32 0.058 0.49
100/10-15-050-09W5/0 64.23 0.74 0.090 0.07 46.87 2.50 0.163 0.41 0.14 8.13 0.112 0.91
139
Appendix C: PDPK Analysis Data
UWI Geometric mean (mD) Average Sandstone (mD) Average Matrix (mD)
16-29-048-06 W5 0.78 1.734431429 0.041479131
16-19-049-05 W5 0.67 1.722460795 0.076281881
08-11-049-05 W5 0.95 2.099908333 0.062743359
06-26-048-05 W5 0.6 0.56379 0.042788336
10-26-049-07 W5 0.7 2.655497917 0.094253466
13-26-048-07 W5 0.77 5.319534444 0.200947083
06-29-049-08 W5 0.55 0.547722222 0.10508079
10-07-048-07 W5 0.33 0.2843 0.063077619
10-26-047-07 W5 0.31 0.175069494 0.051082528
15-27-047-07 W5 0.29 0.207270417 0.047069117
03-07-048-08 W5 0.39 0.363214722 0.02303267
140
Point Depth (m)Klinkenberg corrected liquid
equivalent permeability (mD)Comment
16-29-048-06W5
SAMPLE 1 Burrow Tempestite Matrix
1 1401.4277 0.26 0.26
2 1401.4346 10.4 B 10.4
3 1401.437 0.191 0.191
4 1401.4451 0.561 B 0.561
5 1401.4492 0.0107 0.0107
6 1401.4694 0.254 B 0.254
7 1401.493 0.0449 0.0449
8 1401.4957 0.037 0.037
9 1401.5065 0.00764 0.00764
10 1401.5081 0.0727 0.0727
11 1401.5278 0.216 B 0.216
12 1401.5323 0.0549 0.0549
13 1401.5354 0.0452 0.0452
14 1401.5396 0.805 B 0.805
15 1401.5421 0.0977 0.0977
16 1401.5489 0.0122 0.0122
17 1401.5717 0.306 B 0.306
18 1401.5762 0.0271 0.0271
19 1401.582 0.0176 0.0176
20 1401.5837 1.6 B 1.6
Average: 2.02028571 0.06758769
SAMPLE 2
1 1404.7529 0.158 B 0.158
2 1404.7693 0.0393 0.0393
3 1404.7808 0.00502 0.00502
4 1404.7943 0.0226 0.0226
5 1404.8176 0.01 0.01
6 1404.8299 0.254 T 0.254
7 1404.8315 0.0264 0.0264
8 1404.8374 0.046 0.046
9 1404.8702 0.0819 0.0819
10 1404.8732 0.0469 0.0469
11 1404.8786 0.0102 0.0102
12 1404.906 0.0152 0.0152
13 1404.9096 0.446 B 0.446
14 1404.9205 0.00847 0.00847
15 1404.9327 0.0562 0.0562
16 1404.9481 13.6 T 13.6
Average: 3.6145 0.0306825
141
SAMPLE 3
1 1405.5015 0.209 B 0.209
2 1405.5034 0.0171 0.0171
3 1405.5137 0.019 0.019
4 1405.5219 0.0386 0.0386
5 1405.526 0.317 0.317
6 1405.531 0.899 B 0.899
7 1405.5505 0.029 0.029
8 1405.5526 0.0209 0.0209
9 1405.5749 0.0188 0.0188
10 1405.5753 0.0127 0.0127
11 1405.5767 0.0157 0.0157
12 1405.5906 2.39 B 2.39
13 1405.592 0.74 B 0.74
14 1405.6011 0.0137 0.0137
Average: 1.0595 0.05025
SAMPLE 4
1 1410.9795 0.00969 0.00969
2 1410.9896 0.0804 0.0804
3 1410.9917 0.0167 0.0167
4 1410.9941 0.0984 B 0.0984
5 1410.9953 0.19 B 0.19
6 1411.0128 0.00392 0.00392
7 1411.0259 0.0071 0.0071
8 1411.0347 0.834 B 0.834
9 1411.0388 0.006 0.006
10 1411.0494 0.00985 0.00985
11 1411.0726 0.0486 B 0.0486
12 1411.0863 0.0462 B 0.0462
13 1411.0963 0.0042 0.0042
14 1411.111 0.0699 0.0699
15 1411.1331 0.000504 0.000504
16 1411.139 0.000337 0.000337
17 1411.1435 0.000155 0.000155
Average: 0.24344 0.01739633
142
16-19-049-05W5
SAMPLE 5
1 1236.1162 1.15 B 1.15
2 1236.1223 0.0309 0.0309
3 1236.1288 0.0659 0.0659
4 1236.1341 1.01 B 1.01
5 1236.1434 1.37 B 1.37
6 1236.1534 9.13 B 9.13
7 1236.1566 0.435 0.435
8 1236.1683 0.762 B 0.762
9 1236.1776 0.0325 0.0325
10 1236.1795 0.126 B 0.126
11 1236.1797 0.0133 0.0133
12 1236.1881 15.2 T 15.2
13 1236.1944 4.17 T 4.17
14 1236.1993 0.0523 0.0523
15 1236.2046 0.254 0.254
16 1236.22 0.479 T 0.479
17 1236.2279 1.19 B 1.19
18 1236.236 0.82 B 0.82
Average: 3.21881818 0.12627143
SAMPLE 6
1 1240.1517 0.0175 0.0175
2 1240.1704 0.705 T 0.705
3 1240.1828 0.0184 0.0184
4 1240.1969 0.0723 T 0.0723
5 1240.2012 0.0169 0.0169
6 1240.2048 0.0116 0.0116
7 1240.2142 0.0281 0.0281
8 1240.226 0.49 0.49
9 1240.2333 0.0638 0.0638
10 1240.2452 0.0209 0.0209
11 1240.2485 0.0113 0.0113
12 1240.2566 0.164 0.164
13 1240.2648 0.274 B 0.274
14 1240.2677 0.494 B 0.494
15 1240.2739 0.018 0.018
Average: 0.386325 0.07822727
143
SAMPLE 7
1 1243.7524 0.168 B 0.168
2 1243.7633 0.0403 0.0403
3 1243.7679 0.058 0.058
4 1243.7905 0.0122 0.0122
5 1243.7907 0.012 0.012
6 1243.7922 0.0576 T 0.0576
7 1243.8229 3.6 T 3.6
8 1243.8291 5.48 T 5.48
9 1243.8306 5.07 T 5.07
10 1243.8308 3.77 T 3.77
11 1243.8429 0.0227 0.0227
12 1243.8605 1.17 B 1.17
13 1243.8858 0.00908 0.00908
14 1243.8894 0.00909 0.00909
15 1243.9022 0.184 0.184
16 1243.9172 0.00783 0.00783
17 1243.9217 0.00832 0.00832
18 1243.9247 0.00398 0.00398
19 1243.9266 0.258 B 0.258
20 1243.9268 0.0177 0.0177
Average: 2.4467 0.0321
SAMPLE 8
1 1244.8763 1.4 B 1.4
2 1244.8799 0.276 B 0.276
3 1244.8864 0.183 0.183
4 1244.8991 0.0113 0.0113
5 1244.904 0.00439 0.00439
6 1244.9084 0.00525 0.00525
7 1244.9105 0.0054 0.0054
8 1244.9281 0.181 0.181
9 1244.9287 0.173 0.173
10 1244.9388 0.0113 0.0113
11 1244.9391 0.156 0.156
12 1244.9455 0.0218 0.0218
13 1244.9466 0.284 0.284
14 1244.9613 0.00692 0.00692
15 1244.9821 0.0299 0.0299
16 1244.9823 0.0388 0.0388
17 1244.9916 0.0424 0.0424
18 1245.0142 0.00429 0.00429
19 1245.0161 0.00624 0.00624
Average: 0.838 0.06852882
144
08-11-049-05W5
SAMPLE 9
1 1266.7766 0.0248 0.0248
2 1266.7842 0.0338 0.0338
3 1266.79 0.794 T 0.794
4 1266.7924 0.474 T 0.474
5 1266.8085 0.0674 B 0.0674
6 1266.8094 1.27 B 1.27
7 1266.8174 3.08 B 3.08
8 1266.825 0.0318 0.0318
9 1266.8252 0.0106 0.0106
10 1266.8341 0.336 B 0.336
11 1266.8371 0.377 B 0.377
12 1266.8472 0.0518 0.0518
13 1266.853 0.0367 0.0367
14 1266.8648 0.479 B 0.479
15 1266.8707 1.24 B 1.24
16 1266.8794 0.067 0.067
17 1266.8871 2.49 B 2.49
18 1266.8969 0.0511 0.0511
19 1266.9021 0.0587 0.0587
20 1266.9066 0.168 0.168
Average: 1.06074 0.05343
SAMPLE 10
1 1268.9711 0.00874 0.00874
2 1268.9762 0.0687 0.0687
3 1268.9779 0.00805 0.00805
4 1268.9901 0.201 0.201
5 1268.9965 0.0154 0.0154
6 1269.0056 0.0512 0.0512
7 1269.01 0.0157 0.0157
8 1269.0142 2.06 B 2.06
9 1269.0213 0.257 B 0.257
10 1269.0229 0.019 0.019
11 1269.039 0.0244 0.0244
12 1269.0623 11.5 B 11.5
13 1269.0642 0.464 B 0.464
14 1269.0671 6.09 B 6.09
15 1269.0681 4.49 B 4.49
Average: 4.1435 0.04579889
145
SAMPLE 11
1 1270.9717 0.0249 0.0249
2 1270.9809 0.0663 B 0.0663
3 1270.9844 0.0144 0.0144
4 1270.987 0.0177 0.0177
5 1270.9922 0.288 B 0.288
6 1271.0068 4.49 B 4.49
7 1271.009 0.618 0.618
8 1271.0135 0.496 T 0.496
9 1271.0203 0.0116 0.0116
10 1271.0284 8.97 T 8.97
11 1271.0296 0.0741 0.0741
12 1271.0311 0.0484 0.0484
13 1271.0456 0.0295 0.0295
14 1271.0524 0.0222 0.0222
15 1271.0563 0.334 0.334
16 1271.0651 0.0284 0.0284
17 1271.0692 0.0146 0.0146
Average: 2.86206 0.10315
SAMPLE 12
1 1273.4172 0.018 0.018
2 1273.43 0.331 B 0.331
3 1273.4319 0.074 0.074
4 1273.434 0.0186 0.0186
5 1273.4663 0.0192 0.0192
6 1273.4701 0.231 0.231
7 1273.478 0.0158 0.0158
8 1273.4782 0.0475 0.0475
9 1273.4874 0.34 B 0.34
10 1273.5009 0.329 B 0.329
11 1273.5062 0.00914 0.00914
12 1273.5197 0.0157 0.0157
13 1273.5215 0.0364 0.0364
14 1273.5218 0.0492 0.0492
Average: 0.33333333 0.04859455
146
06-26-048-05W5
SAMPLE 13
1 1268.7841 0.0306 0.0306
2 1268.7899 0.187 0.187
3 1268.8048 0.0342 0.0342
4 1268.8132 0.854 B 0.854
5 1268.8178 0.00761 0.00761
6 1268.8202 0.977 B 0.977
7 1268.8247 0.711 B 0.711
8 1268.8262 0.673 B 0.673
9 1268.8342 0.0207 0.0207
10 1268.8491 0.164 0.164
11 1268.8585 0.0176 0.0176
12 1268.8636 0.0143 0.0143
13 1268.8698 0.0374 0.0374
14 1268.8903 0.0401 0.0401
15 1268.8928 0.0279 0.0279
16 1268.8995 2.05 B 2.05
17 1268.9022 0.0166 0.0166
18 1268.9024 0.0225 0.0225
19 1268.9171 0.0153 0.0153
20 1268.9255 0.0151 0.0151
Average: 1.053 0.043394
SAMPLE 14
1 1270.3087 0.0261 0.0261
2 1270.3182 0.0119 0.0119
3 1270.3253 0.00494 0.00494
4 1270.3332 0.525 B 0.525
5 1270.3334 0.415 B 0.415
6 1270.359 0.279 0.279
7 1270.3664 0.225 B 0.225
8 1270.3765 1.84 B 1.84
9 1270.3838 0.0428 0.0428
10 1270.3913 0.00649 0.00649
11 1270.3971 0.0407 0.0407
12 1270.3986 0.00468 0.00468
13 1270.4021 0.009 0.009
14 1270.42 0.153 B 0.153
15 1270.4343 0.00581 0.00581
16 1270.4559 0.12 0.12
Average: 0.6316 0.05012909
147
SAMPLE 15
1 1272.3158 0.0126 0.0126
2 1272.3229 0.0151 0.0151
3 1272.3267 0.0041 0.0041
4 1272.3394 0.0393 0.0393
5 1272.3481 0.178 B 0.178
6 1272.3543 0.28 B 0.28
7 1272.3563 0.0677 0.0677
8 1272.3774 0.0513 0.0513
9 1272.3911 0.0194 0.0194
10 1272.4239 0.102 T 0.102
11 1272.4264 0.0945 T 0.0945
12 1272.4266 0.198 T 0.198
13 1272.4314 0.0309 0.0309
14 1272.4435 0.00651 0.00651
15 1272.452 0.0131 0.0131
16 1272.4632 0.0221 0.0221
Average: 0.1705 0.02564636
SAMPLE 16
1 1276.0699 0.00821 0.00821
2 1276.0727 0.0223 0.0223
3 1276.084 0.0894 0.0894
4 1276.0958 0.0352 0.0352
5 1276.1059 0.0126 0.0126
6 1276.1131 0.0553 T 0.0553
7 1276.1199 0.649 B 0.649
8 1276.1224 0.382 B 0.382
9 1276.1294 0.506 B 0.506
10 1276.1383 0.0357 0.0357
11 1276.1495 0.0173 0.0173
12 1276.1672 0.0169 0.0169
13 1276.1732 0.408 B 0.408
14 1276.1866 0.169 0.169
15 1276.1918 0.0382 0.0382
16 1276.2049 0.0449 0.0449
17 1276.2108 0.0925 0.0925
18 1276.2266 0.028 0.028
19 1276.2294 0.0737 0.0737
20 1276.2308 0.156 0.156
21 1276.2522 0.0276 0.0276
22 1276.257 0.0299 0.0299
23 1276.2681 0.0383 0.0383
Average: 0.40006 0.05198389
148
10-26-049-07W5
SAMPLE 17
1 1334.1541 0.397 B 0.397
2 1334.1621 0.0501 0.0501
3 1334.1699 0.299 B 0.299
4 1334.183 2.45 B 2.45
5 1334.1967 0.0312 0.0312
6 1334.1969 1.59 B 1.59
7 1334.2017 0.364 B 0.364
8 1334.2144 0.145 0.145
9 1334.2146 0.487 B 0.487
10 1334.2216 3.25 B 3.25
11 1334.2267 0.0193 0.0193
12 1334.2428 0.959 B 0.959
13 1334.2581 0.153 0.153
14 1334.2583 0.536 B 0.536
15 1334.2617 0.1 0.1
16 1334.2619 1.64 B 1.64
17 1334.2657 2.1 B 2.1
18 1334.272 0.294 B 0.294
Average: 1.19716667 0.0831
SAMPLE 18
1 1337.8388 0.252 0.252
2 1337.8423 0.213 0.213
3 1337.8516 0.0308 0.0308
4 1337.8661 0.188 0.188
5 1337.8774 0.201 B 0.201
6 1337.8932 0.0838 0.0838
7 1337.9172 0.0427 0.0427
8 1337.9195 0.608 0.608
9 1337.9286 0.434 B 0.434
10 1337.9288 0.526 B 0.526
11 1337.9322 2.19 B 2.19
12 1337.9627 4.59 T 4.59
13 1337.9629 0.038 0.038
14 1337.9643 11.2 T 11.2
15 1337.9645 10.2 T 10.2
16 1337.9874 0.0122 0.0122
17 1338.0013 0.36 B 0.36
Average: 3.712625 0.16316667
149
SAMPLE 19
1 1339.9958 0.0331 0.0331
2 1339.9982 0.791 B 0.791
3 1340.0011 1.11 B 1.11
4 1340.0068 0.929 B 0.929
5 1340.0079 0.91 B 0.91
6 1340.0168 0.00618 0.00618
7 1340.0469 0.0223 0.0223
8 1340.0506 0.0484 0.0484
9 1340.0508 0.637 B 0.637
10 1340.0543 0.046 0.046
11 1340.0579 0.267 0.267
12 1340.0811 0.0154 0.0154
13 1340.0834 0.015 0.015
14 1340.084 0.0436 0.0436
15 1340.0871 0.00711 0.00711
16 1340.1271 0.258 0.258
17 1340.13 0.0328 0.0328
Average: 0.8754 0.06624083
SAMPLE 20
1 1345.1149 0.0534 0.0534
2 1345.1162 0.228 0.228
3 1345.1227 0.0653 0.0653
4 1345.1297 10.5 B 10.5
5 1345.1329 3.27 B 3.27
6 1345.1356 9.89 B 9.89
7 1345.1518 0.00477 0.00477
8 1345.1796 0.062 0.062
9 1345.2009 0.0178 0.0178
10 1345.2161 0.0131 0.0131
11 1345.2192 0.18 0.18
12 1345.2281 0.014 0.014
13 1345.2419 0.2 B 0.2
14 1345.2553 0.0419 0.0419
15 1345.2609 0.324 B 0.324
16 1345.2692 0.0293 0.0293
Average: 4.8368 0.06450636
150
13-26-048-07W5
SAMPLE 21
1 1402.6117 2.32 B 2.32
2 1402.6259 0.333 B 0.333
3 1402.6264 0.56 B 0.56
4 1402.6319 1.76 B 1.76
5 1402.6512 51.6 B 51.6
6 1402.6533 54.8 B 54.8
7 1402.6565 65.3 B 65.3
8 1402.6685 1.28 B 1.28
9 1402.6716 12.8 B 12.8
10 1402.6866 0.189 0.189
11 1402.7017 0.106 0.106
12 1402.7174 0.0543 0.0543
13 1402.7241 1.01 B 1.01
14 1402.7259 3.19 B 3.19
15 1402.7477 0.0744 T 0.0744
16 1402.7509 0.218 T 0.218
17 1402.7665 1.48 B 1.48
18 1402.7708 0.14 0.14
19 1402.7787 0.861 0.861
20 1402.785 2.13 B 2.13
Average: 13.2570267 0.27006
SAMPLE 22
1 1406.242 0.019 0.019
2 1406.2611 0.148 0.148
3 1406.263 0.0443 0.0443
4 1406.2664 0.338 0.338
5 1406.3003 1.02 1.02
6 1406.305 0.0239 0.0239
7 1406.3074 0.0463 0.0463
8 1406.3134 0.617 0.617
9 1406.3423 2.84 B 2.84
10 1406.3472 0.0307 0.0307
11 1406.3474 0.221 0.221
12 1406.3538 0.887 B 0.887
13 1406.3608 0.0731 0.0731
14 1406.3704 0.91 B 0.91
15 1406.3771 0.111 0.111
Average: 1.54566667 0.22435833
151
SAMPLE 23
1 1407.0165 0.0955 0.0955
2 1407.0167 0.265 0.265
3 1407.0175 0.157 0.157
4 1407.0267 0.0629 0.0629
5 1407.0322 0.506 0.506
6 1407.0485 1.04 B 1.04
7 1407.0537 0.23 B 0.23
8 1407.0701 1.64 T 1.64
9 1407.0703 2.83 T 2.83
10 1407.0705 1.54 T 1.54
11 1407.0729 0.829 T 0.829
12 1407.0926 0.0799 0.0799
13 1407.0958 0.053 0.053
14 1407.1235 0.372 0.372
15 1407.1239 8.04 T 8.04
16 1407.1243 26.8 T 26.8
17 1407.1381 0.062 0.062
18 1407.148 13.8 T 13.8
19 1407.1494 0.103 0.103
Average: 6.30544444 0.17563
SAMPLE 24
1 1413.0626 0.101 0.101
2 1413.0723 0.129 0.129
3 1413.0791 0.0183 0.0183
4 1413.082 0.203 0.203
5 1413.0836 0.239 0.239
6 1413.0858 0.0212 0.0212
7 1413.0928 0.17 B 0.17
8 1413.1016 0.0311 0.0311
9 1413.1102 0.424 0.424
10 1413.1148 0.135 0.135
11 1413.1154 0.0358 0.0358
Average: 0.17 0.13374
152
06-29-049-08W5
SAMPLE 25
1 1493.7398 1.64 B 1.64
2 1493.7526 1.49 B 1.49
3 1493.7617 0.133 0.133
4 1493.7619 0.136 0.136
5 1493.7796 0.154 0.154
6 1493.7799 1.56 B 1.56
7 1493.7841 0.238 0.238
8 1493.7917 0.812 B 0.812
9 1493.7966 0.872 B 0.872
10 1493.8025 0.19 0.19
11 1493.8141 0.225 0.225
12 1493.8177 0.655 B 0.655
13 1493.825 0.566 0.566
14 1493.8257 0.164 0.164
15 1493.8281 0.241 0.241
Average: 1.1715 0.22744444
SAMPLE 26
1 1497.4896 0.0377 0.0377
2 1497.5131 0.327 0.327
3 1497.5166 0.0166 0.0166
4 1497.5279 0.0156 0.0156
5 1497.5523 0.09 0.09
6 1497.5583 0.0488 0.0488
7 1497.5705 0.0129 0.0129
8 1497.5763 0.307 B 0.307
9 1497.5815 0.106 B 0.106
10 1497.6102 0.0876 0.0876
11 1497.6158 0.0403 0.0403
12 1497.6272 0.0327 0.0327
13 1497.6331 0.0118 0.0118
14 1497.6363 0.0152 0.0152
15 1497.6374 0.294 B 0.294
16 1497.6398 0.31 0.31
17 1497.6496 0.0981 0.0981
Average: 0.23566667 0.08173571
153
SAMPLE 27
1 1499.6153 0.236 B 0.236
2 1499.6216 0.0138 0.0138
3 1499.6343 0.0211 0.0211
4 1499.6419 0.0269 0.0269
5 1499.6667 0.0145 0.0145
6 1499.6681 0.0614 0.0614
7 1499.685 0.0253 0.0253
8 1499.6939 0.035 0.035
9 1499.7047 0.0768 B
10 1499.7063 0.0833 B
11 1499.7067 0.0729 B
12 1499.7396 0.0127 0.0127
13 1499.7653 0.246 0.246
14 1499.7771 0.00953 0.00953
Average: 0.236 0.046623
SAMPLE 28
1 1500.8493 0.0341 B
2 1500.8534 0.0836 0.0836
3 1500.8581 0.0388 0.0388
4 1500.8823 0.199 B
5 1500.8895 0.0137 0.0137
6 1500.8911 0.0837 0.0837
7 1500.8932 0.0157 0.0157
8 1500.9173 0.0177 0.0177
9 1500.9199 0.0151 0.0151
10 1500.9326 0.0685 B
11 1500.9328 0.0652 B
12 1500.942 0.28 0.28
13 1500.9644 0.0516 0.0516
14 1500.9754 0.0453 0.0453
15 1500.9832 0.316 B
Average: 0.06452
154
10-07-084-07W5
SAMPLE 29
1 1507.983 0.0282 0.0282
2 1507.9921 0.0397 0.0397
3 1507.9969 0.0891 B
4 1508.0072 0.0576 B
5 1508.0142 0.0146 B
6 1508.0177 0.0192 B
7 1508.0251 0.0265 0.0265
8 1508.0282 0.162 0.162
9 1508.0362 0.184 0.184
10 1508.0388 0.0231 B
11 1508.0485 0.0124 0.0124
12 1508.0595 0.0415 0.0415
13 1508.0655 0.0886 0.0886
14 1508.0735 0.43 0.43
15 1508.086 0.0428 0.0428
16 1508.0942 0.411 B 0.411
17 1508.108 0.0176 0.0176
18 1508.1206 0.0573 0.0573
19 1508.1295 0.0372 0.0372
20 1508.1413 0.0943 0.0943
Average: 0.411 0.09015
SAMPLE 30
1 1510.7401 0.0457 0.0457
2 1510.7492 0.0385 0.0385
3 1510.7577 0.265 B 0.265
4 1510.7774 0.15 0.15
5 1510.7905 0.0294 0.0294
6 1510.8089 0.0127 0.0127
7 1510.8157 0.218 0.218
8 1510.8248 0.0161 0.0161
9 1510.8396 0.0126 0.0126
10 1510.8487 0.457 T 0.457
11 1510.8495 0.0319 0.0319
12 1510.8497 0.0251 0.0251
13 1510.8824 0.0408 0.0408
14 1510.8867 0.0329 0.0329
15 1510.8897 0.0112 0.0112
16 1510.9021 0.0508 0.0508
17 1510.9056 0.0259 0.0259
18 1510.9168 0.064 0.064
Average: 0.361 0.05035
155
SAMPLE 31
1 1515.5194 0.0104 0.0104
2 1515.5294 0.0256 0.0256
3 1515.543 0.0398 0.0398
4 1515.5489 0.0666 0.0666
5 1515.5762 0.0453 0.0453
6 1515.5992 0.091 0.091
7 1515.6051 0.0712 0.0712
8 1515.6287 0.0319 0.0319
9 1515.6318 0.0544 0.0544
10 1515.6499 0.0402 0.0402
11 1515.6642 0.14 0.14
12 1515.6668 0.0394 0.0394
13 1515.683 0.193 0.193
14 1515.6875 0.0349 0.0349
15 1515.7021 0.0189 0.0189
16 1515.71 0.0824 0.0824
17 1515.7135 0.0597 0.0597
18 1515.7509 0.044 0.044
Average: 0.06048333
SAMPLE 32
1 1516.2585 0.0945 0.0945
2 1516.2666 0.0237 0.0237
3 1516.2768 0.0233 B
4 1516.3165 0.0156 B
5 1516.3168 0.0264 0.0264
6 1516.3214 0.197 B 0.197
7 1516.3438 0.0282 0.0282
8 1516.374 0.0335 0.0335
9 1516.384 0.0486 0.0486
10 1516.3903 0.0307 T 0.0307
11 1516.3905 0.015 T 0.015
12 1516.3953 0.0135 0.0135
13 1516.4101 0.0396 0.0396
14 1516.4103 0.0192 0.0192
15 1516.4366 0.0135 0.0135
16 1516.447 0.186 0.186
17 1516.4564 0.0569 0.0569
18 1516.4623 0.0639 0.0639
19 1516.47 0.1 0.1
20 1516.483 0.00918 0.00918
21 1516.5088 0.0801 0.0801
Average: 0.0809 0.05132714
156
10-26-047-07W5
SAMPLE 33
1 1539.8209 0.125 B 0.125
2 1539.8296 0.491 B 0.491
3 1539.8368 0.318 B 0.318
4 1539.8454 0.0205 0.0205
5 1539.8657 0.0328 0.0328
6 1539.8754 0.328 0.328
7 1539.8785 0.0437 0.0437
8 1539.8911 0.221 B 0.221
9 1539.8932 0.0466 0.0466
10 1539.8985 0.0698 0.0698
11 1539.9206 0.153 B 0.153
12 1539.9273 0.0247 0.0247
13 1539.9336 0.15 0.15
14 1539.9404 0.471 B 0.471
15 1539.9675 0.0274 0.0274
16 1539.9799 0.138 B 0.138
Average: 0.27385714 0.08261111
SAMPLE 34
1 1544.5984 0.22 B 0.22
2 1544.6021 0.0388 0.0388
3 1544.6023 0.0733 B 0.0733
4 1544.614 0.0126 0.0126
5 1544.6142 0.0825 0.0825
6 1544.6241 0.0096 0.0096
7 1544.6307 0.101 0.101
8 1544.6527 0.0942 0.0942
9 1544.6719 0.166 B 0.166
10 1544.6724 0.175 B 0.175
11 1544.6826 0.288 B 0.288
12 1544.6909 0.281 B 0.281
13 1544.6985 0.117 B 0.117
14 1544.7133 0.158 B 0.158
15 1544.7143 0.0192 0.0192
16 1544.7176 0.098 0.098
17 1544.7377 0.0567 0.0567
18 1544.7459 0.00965 0.00965
Average: 0.1847875 0.052225
157
SAMPLE 35
1 1546.4284 0.0426 0.0426
2 1546.4314 0.0146 0.0146
3 1546.4411 0.00615 0.00615
4 1546.4495 0.0412 0.0412
5 1546.4497 0.0428 0.0428
6 1546.4873 0.0865 0.0865
7 1546.4927 0.0108 0.0108
8 1546.4991 0.0688 0.0688
9 1546.5101 0.0105 0.0105
10 1546.5104 0.128 0.128
11 1546.5361 0.0438 0.0438
12 1546.5436 0.0433 0.0433
13 1546.5506 0.0147 0.0147
14 1546.5749 0.0253 B 0.0253
15 1546.5983 0.0673 0.0673
16 1546.6042 0.0339 0.0339
Average: 0.0253 0.04366333
SAMPLE 36
1 1548.5231 0.0268 0.0268
2 1548.5268 0.0257 0.0257
3 1548.5416 0.0256 0.0256
4 1548.5431 0.022 0.022
5 1548.5475 0.0155 0.0155
6 1548.5625 0.00909 0.00909
7 1548.6055 0.00777 0.00777
8 1548.6077 0.0278 0.0278
9 1548.6151 0.126 B 0.126
10 1548.6153 0.245 B 0.245
11 1548.6209 0.0534 0.0534
12 1548.6229 0.00799 0.00799
13 1548.6297 0.0106 0.0106
14 1548.6348 0.00571 0.00571
15 1548.6446 0.0147 0.0147
16 1548.6543 0.0288 0.0288
17 1548.6689 0.106 0.106
18 1548.672 0.067 T
19 1548.6848 0.278 B 0.278
Average: 0.21633333 0.02583067
158
15-27-047-07W5
SAMPLE 37
1 1527.7945 0.158 B 0.158
2 1527.8019 0.627 B 0.627
3 1527.8037 0.327 B 0.327
4 1527.825 0.152 B 0.152
5 1527.8293 0.299 B 0.299
6 1527.8324 0.267 B 0.267
7 1527.8362 0.149 B 0.149
8 1527.8391 0.0649 0.0649
9 1527.8514 0.0923 0.0923
10 1527.8537 0.0902 0.0902
11 1527.8574 0.0744 0.0744
12 1527.87 0.0156 0.0156
13 1527.8749 0.132 0.132
14 1527.8794 0.213 B 0.213
15 1527.903 0.0248 0.0248
16 1527.9118 0.0664 0.0664
17 1527.912 0.0358 0.0358
18 1527.9183 0.0282 0.0282
19 1527.9229 0.0302 0.0302
Average: 0.274 0.05952727
SAMPLE 38
1 1529.0698 0.0108 0.0108
2 1529.0887 0.0851 0.0851
3 1529.0922 0.0281 0.0281
4 1529.0938 0.0209 0.0209
5 1529.099 0.0101 0.0101
6 1529.1053 0.00664 0.00664
7 1529.1068 0.0105 0.0105
8 1529.1217 0.0255 B 0.0255
9 1529.1446 0.0154 0.0154
10 1529.1484 0.0261 0.0261
11 1529.1576 0.0393 0.0393
12 1529.1624 0.199 B 0.199
13 1529.165 0.0288 0.0288
14 1529.2114 0.0397 0.0397
15 1529.2175 0.359 B 0.359
16 1529.2192 0.0784 0.0784
17 1529.2204 0.185 B 0.185
Average: 0.192125 0.03075692
159
SAMPLE 39
1 1533.8961 0.064 0.064
2 1533.8991 0.0626 B 0.0626
3 1533.9066 0.0349 B 0.0349
4 1533.9254 0.011 0.011
5 1533.9329 0.117 B 0.117
6 1533.9418 0.0192 B 0.0192
7 1533.9533 0.154 B 0.154
8 1533.9647 0.0088 0.0088
9 1533.9673 0.0141 0.0141
10 1534.0034 0.0457 T 0.0457
11 1534.0075 0.0468 T 0.0468
12 1534.0138 0.0637 T 0.0637
13 1534.0417 0.165 B 0.165
14 1534.0466 0.154 B 0.154
0.08629 0.024475
SAMPLE 40
1 1536.7177 0.179 B 0.179
2 1536.7621 0.0272 0.0272
3 1536.7723 0.018 0.018
4 1536.7875 0.033 0.033
5 1536.8142 0.365 B 0.365
6 1536.8158 0.572 0.572
7 1536.8221 0.0253 0.0253
8 1536.8369 0.038 0.038
9 1536.8533 0.0436 0.0436
10 1536.8628 0.00749 0.00749
11 1536.885 0.286 T 0.286
12 1536.8973 0.0132 0.0132
13 1536.9019 0.0183 0.0183
14 1536.9081 0.0126 0.0126
Average: 0.27666667 0.07351727
160
03-07-048-08W5
SAMPLE 41
1 1647.579 0.00749 0.00749
2 1647.5963 0.00551 0.00551
3 1647.5971 0.00511 0.00511
4 1647.6106 0.00757 0.00757
5 1647.6108 0.00729 0.00729
6 1647.6145 0.0154 0.0154
7 1647.6146 0.364 B 0.364
8 1647.6237 0.0129 0.0129
9 1647.6252 0.238 B 0.238
10 1647.6344 0.00955 0.00955
11 1647.6373 0.012 0.012
12 1647.6545 0.00679 0.00679
13 1647.6566 0.0109 0.0109
14 1647.6579 0.0261 0.0261
15 1647.6593 0.0116 0.0116
16 1647.6685 0.0653 0.0653
17 1647.6703 0.0245 0.0245
18 1647.677 0.0545 0.0545
Average: 0.301 0.01765688
SAMPLE 42
1 1648.5045 0.0174 0.0174
2 1648.525 0.0406 T 0.0406
3 1648.5314 0.0281 T 0.0281
4 1648.5421 0.0343 0.0343
5 1648.5451 0.0396 T 0.0396
6 1648.5552 0.0523 0.0523
7 1648.5633 0.0122 0.0122
8 1648.5642 0.00541 0.00541
9 1648.5811 0.0215 B 0.0215
10 1648.5921 0.0049 0.0049
11 1648.5961 0.0364 B 0.0364
12 1648.6053 0.0144 B 0.0144
13 1648.6081 0.0203 B 0.0203
14 1648.6213 0.0185 B 0.0185
15 1648.6273 0.0181 0.0181
16 1648.6331 0.0129 0.0129
17 1648.6485 0.0277 B 0.0277
18 1648.6623 0.0214 0.0214
19 1648.6657 0.0718 0.0718
20 1648.6826 0.022 0.022
Average: 0.02745556 0.02479182
161
SAMPLE 43
1 1652.7576 0.0238 T 0.0238
2 1652.7769 0.0216 0.0216
3 1652.7881 0.017 0.017
4 1652.7883 0.0114 0.0114
5 1652.7995 2.18 B 2.18
6 1652.8024 0.0513 0.0513
7 1652.8073 0.17 0.17
8 1652.8121 0.0288 0.0288
9 1652.8151 0.038 0.038
10 1652.8299 0.0187 0.0187
11 1652.8331 0.0134 0.0134
12 1652.8367 0.0893 0.0893
13 1652.8408 0.0315 0.0315
14 1652.8641 0.026 0.026
15 1652.8676 0.0422 0.0422
16 1652.8681 0.0132 0.0132
17 1652.8844 0.00966 0.00966
Average: 1.1019 0.03792824
SAMPLE 44
1 1654.9699 0.00599 0.00599
2 1654.9733 0.00677 0.00677
3 1654.9828 0.0183 0.0183
4 1654.99 0.0337 B 0.0337
5 1655.0111 0.0117 0.0117
6 1655.0223 0.00921 B 0.00921
7 1655.0563 0.0276 0.0276
8 1655.0697 0.00999 0.00999
9 1655.0823 0.00895 0.00895
10 1655.0883 0.023 0.023
11 1655.0931 0.00948 0.00948
12 1655.0964 0.0103 0.0103
13 1655.1135 0.0214 0.0214
14 1655.123 0.00212 0.00212
15 1655.1264 0.0039 0.0039
16 1655.1546 0.0246 B 0.0246
17 1655.1549 0.0108 0.0108
18 1655.1606 0.0146 0.0146
19 1655.1855 0.00316 0.00316
Average: 0.02250333 0.01175375
162
Appendix D: Horizontal Well Data
163
UWIMid Hole
(easting)
Mid Hole
(westing)
Rig Release
Date
Monthly
Oil First
Prod (m3)
Monthly
Oil First(3)
Prod (m3)
100/16-14-047-05W5/0 659001.88 5881611.79 1-8-2011 124.7 1213.4
100/13-16-047-05W5/0 656053.37 5881692.51 11-11-2011 384.6 1704.5
100/16-17-047-05W5/0 654121.80 5881462.16 11-25-2010 313.7 2489.5
102/05-19-047-05W5/0 652772.89 5882276.36 10-24-2010 89.6 1187.4
100/13-19-047-05W5/0 652812.68 5882965.37 3-2-2012 308.1 1728.4
100/05-20-047-05W5/0 654422.23 5882280.15 6-28-2010 1018.2 2454.8
100/16-20-047-05W5/0 654304.30 5883069.80 11-23-2009 302.3 948.6
100/04-21-047-05W5/0 656046.86 5882034.32 12-8-2010 846.2 2627.3
100/05-21-047-05W5/0 656046.73 5882248.74 12-10-2011 138.9 654.9
100/09-21-047-05W5/0 655904.53 5882510.13 8-20-2010 284.8 1113.3
100/14-22-047-05W5/0 657304.28 5882574.18 9-5-2009 284.3 647.0
100/13-26-047-05W5/0 658562.08 5884098.27 9-6-2012 357.1 1875.0
100/14-26-047-05W5/0 658760.78 5884108.29 8-27-2012 407.8 1908.3
103/08-27-047-05W5/0 657361.23 5883850.92 2-2-2010 646.9 1160.9
100/16-27-047-05W5/0 657348.89 5884785.29 11-21-2009 658.8 1383.2
100/13-28-047-05W5/0 655344.70 5883919.35 11-4-2012 338.7 1915.5
100/14-28-047-05W5/0 655559.62 5883919.52 10-25-2012 148.5 1734.2
100/15-28-047-05W5/0 656191.94 5884112.58 6-25-2012 698.6 1907.9
102/16-28-047-05W5/0 656418.06 5884115.72 3-13-2010 871.8 1782.7
100/12-29-047-05W5/0 654602.79 5884541.51 12-20-2012 361.5 1765.0
102/12-29-047-05W5/0 654612.22 5884415.50 1-7-2013 190.0 1415.8
100/13-29-047-05W5/0 654591.12 5884665.32 12-11-2012 186.7 1577.7
102/14-29-047-05W5/0 654643.44 5884786.31 12-22-2009 367.8 1240.0
100/01-34-047-05W5/0 657979.82 5886004.76 3-24-2012 1381.4 3096.2
102/01-34-047-05W5/0 657856.56 5885986.55 3-18-2013 32.7 1290.6
100/02-34-047-05W5/0 657725.94 5885995.34 1-29-2012 1021.7 3681.2
100/03-34-047-05W5/0 657293.04 5886300.43 1-18-2013 1389.5 3029.7
100/12-24-047-06W5/0 651032.39 5882748.74 10-14-2010 958.4 1680.6
100/04-25-047-06W5/0 651001.66 5883495.80 9-12-2010 499.3 1333.9
100/05-25-047-06W5/0 650985.58 5883780.24 7-15-2010 1096.2 1697.3
100/13-30-047-06W5/0 641910.59 5883516.36 2-2-2012 267.8 1935.5
102/16-24-047-07W5/0 641666.73 5881815.60 2-2-2013 326.4 773.5
102/03-25-047-07W5/0 640466.85 5883752.93 7-8-2013 403.6 2110.8
102/04-25-047-07W5/0 640915.80 5883662.31 8-7-2011 50.5 150.6
164
103/04-25-047-07W5/0 640176.26 5883751.69 6-25-2013 346.7 1644.9
100/15-25-047-07W5/0 641372.76 5883554.69 9-24-2011 1063.9 3031.2
102/16-25-047-07W5/0 641690.53 5883367.75 10-19-2012 798.1 2009.3
102/10-26-047-07W5/0 639750.02 5884137.31 6-15-2013 218.7 1572.8
102/09-27-047-07W5/0 637553.61 5883700.10 7-28-2012 609.8 1788.3
100/09-29-047-07W5/0 634788.69 5882989.59 12-19-2010 26.2 214.5
102/07-33-047-07W5/0 636438.93 5884354.17 7-17-2012 352.0 1322.4
102/14-22-047-09W5/0 617742.68 5881634.75 2-1-2010 0.0 78.6
100/15-22-047-09W5/0 617906.85 5881581.92 2-16-2010 0.0 224.0
100/10-28-047-09W5/0 617233.43 5883900.67 4-2-2009 255.9 1088.1
103/14-28-047-09W5/0 617125.67 5883961.87 7-9-2009 0.1 463.8
100/01-04-048-04W5/0 665613.31 5887025.49 1-12-2010 0.0 79.3
100/13-07-048-04W5/0 662394.23 5889751.63 2-4-2013 157.0 805.2
100/01-16-048-04W5/0 665290.84 5890360.99 9-24-2011 454.6 1239.7
100/08-16-048-04W5/0 665256.53 5890900.69 3-21-2011 319.7 1377.3
100/09-16-048-04W5/0 665427.28 5891316.51 2-23-2012 134.7 1613.8
100/06-17-048-04W5/0 664184.94 5890783.29 2-28-2010 584.8 1080.0
100/13-17-048-04W5/0 663892.40 5891647.74 10-26-2010 696.3 1921.9
100/04-18-048-04W5/0 662457.03 5890492.82 8-29-2012 143.3 143.3
100/05-18-048-04W5/0 662449.34 5890712.36 8-18-2012 95.8 95.8
100/12-18-048-04W5/2 662441.02 5890927.14 8-5-2012 46.8 1590.4
100/13-18-048-04W5/0 662457.24 5891143.63 7-21-2012 76.9 1259.3
100/04-19-048-04W5/0 662255.49 5891946.20 11-9-2011 838.3 2229.5
100/05-19-048-04W5/0 662248.84 5892163.82 3-22-2011 90.6 2155.7
100/12-19-048-04W5/0 662222.78 5892627.19 3-3-2012 1221.7 2926.9
100/13-19-048-04W5/0 662211.93 5892920.99 8-12-2011 0.0 1531.2
100/01-20-048-04W5/0 663737.82 5892006.91 9-5-2011 338.2 2509.0
102/08-20-048-04W5/0 663728.35 5892241.86 8-28-2011 154.4 1490.7
102/09-20-048-04W5/0 663813.46 5892714.79 8-20-2011 0.0 778.8
100/01-21-048-04W5/0 665417.79 5891628.18 2-14-2012 168.3 1761.6
100/12-21-048-04W5/0 665777.50 5892555.02 11-21-2012 211.0 508.6
100/13-21-048-04W5/0 664607.74 5892393.36 2-7-2012 45.4 1448.4
100/01-28-048-04W5/0 665378.76 5893476.98 2-10-2013 208.0 611.8
100/04-29-048-04W5/0 663886.64 5893351.25 2-16-2013 194.5 718.6
102/04-29-048-04W5/0 663878.94 5893548.35 3-1-2013 170.0 1157.5
165
100/01-30-048-04W5/0 662065.66 5893403.20 11-17-2011 264.3 2012.2
100/09-30-048-04W5/0 661873.85 5894029.78 9-25-2012 651.5 1936.5
100/01-31-048-04W5/0 662085.45 5894914.82 10-28-2012 35.5 458.4
100/09-31-048-04W5/0 662049.83 5895687.13 11-20-2012 130.6 376.5
103/12-33-048-04W5/0 665445.40 5895997.68 3-20-2012 231.3 949.4
102/13-33-048-04W5/0 665434.25 5896286.36 3-12-2012 417.1 2267.0
103/13-33-048-04W5/0 665437.99 5896135.33 9-7-2012 43.5 1231.7
100/11-03-048-05W5/0 656788.90 5887954.99 2-15-2013 87.0 1181.5
100/16-03-048-05W5/0 657860.17 5887557.71 12-7-2009 3.6 542.1
100/13-09-048-05W5/0 655581.55 5889626.77 6-26-2011 368.3 857.2
100/01-10-048-05W5/0 657288.92 5888317.80 7-25-2012 889.4 2520.2
100/08-10-048-05W5/0 657279.62 5888616.83 7-16-2012 651.4 1946.0
100/09-10-048-05W5/0 657202.17 5889279.71 8-18-2012 131.5 1666.3
102/09-10-048-05W5/0 657206.16 5889164.99 8-10-2012 101.1 1928.4
100/16-10-048-05W5/0 657436.84 5889699.79 11-9-2009 392.9 791.4
100/08-13-048-05W5/0 660437.65 5890641.14 8-4-2010 341.8 1044.7
100/13-13-048-05W5/0 660679.12 5891535.11 1-12-2013 270.9 2262.0
100/05-14-048-05W5/0 658929.56 5890603.86 7-13-2010 62.0 501.2
102/16-15-048-05W5/0 657069.84 5891241.70 2-22-2010 213.7 470.5
102/01-16-048-05W5/0 655726.58 5890020.21 2-9-2012 1480.3 2709.3
100/08-16-048-05W5/0 655824.96 5890145.45 11-23-2009 1253.6 2439.3
100/09-16-048-05W5/0 655608.59 5890818.79 12-19-2011 1125.4 2977.6
100/16-16-048-05W5/0 655597.78 5891213.46 1-14-2012 1659.2 3131.2
100/04-17-048-05W5/0 654271.22 5890040.41 1-9-2012 567.1 2339.3
100/05-17-048-05W5/0 654261.24 5890216.10 9-2-2011 547.9 2051.3
100/12-17-048-05W5/0 654119.12 5890585.70 6-26-2010 1074.9 1835.9
100/13-17-048-05W5/0 654150.70 5891204.97 11-11-2010 713.9 1578.6
100/07-18-048-05W5/0 652862.52 5890060.65 1-27-2011 237.1 739.3
100/12-18-048-05W5/0 652502.19 5890783.41 2-8-2011 820.9 1637.9
102/14-18-048-05W5/0 652727.60 5890973.82 1-23-2010 360.8 638.0
102/04-19-048-05W5/0 652491.36 5891362.44 9-3-2012 638.2 1913.0
100/08-19-048-05W5/0 652240.83 5892149.86 8-17-2012 1258.0 2189.7
102/08-19-048-05W5/0 652295.27 5892006.48 2-18-2013 1415.3 2036.8
100/09-19-048-05W5/0 652194.25 5892283.15 10-27-2010 787.4 1255.6
103/16-19-048-05W5/0 652231.87 5892468.99 8-16-2011 471.7 1305.9
166
100/04-20-048-05W5/0 654094.97 5891645.55 9-2-2011 371.8 1378.8
100/05-20-048-05W5/0 654090.51 5891848.48 3-27-2011 770.9 1449.1
100/12-20-048-05W5/0 653996.13 5892485.27 3-28-2012 466.1 1211.6
100/04-21-048-05W5/0 655669.72 5891620.46 7-2-2010 386.1 1246.3
102/12-21-048-05W5/0 655684.49 5892592.70 8-22-2012 363.6 1237.4
103/13-21-048-05W5/0 655678.95 5892826.78 9-3-2012 293.5 1191.9
100/02-22-048-05W5/0 658006.25 5891760.44 12-1-2011 169.1 794.4
100/07-22-048-05W5/0 657999.32 5891994.75 11-19-2011 266.5 1346.7
100/10-22-048-05W5/0 656907.65 5892552.77 6-29-2011 251.3 1481.0
100/01-23-048-05W5/0 658953.48 5891791.46 9-10-2011 60.4 884.5
102/08-23-048-05W5/0 658945.30 5892085.08 8-29-2011 84.0 950.3
100/11-23-048-05W5/0 658056.81 5892613.24 7-30-2011 67.1 1284.4
100/14-23-048-05W5/0 658051.44 5892824.83 7-16-2011 212.1 1520.3
102/16-23-048-05W5/0 659124.58 5893035.87 10-12-2010 515.2 1677.2
100/04-24-048-05W5/0 660616.74 5891719.56 8-15-2010 0.0 1182.1
100/05-24-048-05W5/0 660551.55 5892133.83 3-14-2010 466.6 1803.9
100/12-24-048-05W5/0 660758.58 5892535.20 9-14-2010 1380.3 3154.5
102/12-24-048-05W5/0 659389.16 5892494.89 8-25-2010 792.6 1612.4
103/12-24-048-05W5/0 659920.52 5893334.95 8-18-2011 419.7 2219.0
103/13-24-048-05W5/0 660744.10 5892931.34 2-19-2013 126.4 983.7
102/04-25-048-05W5/0 660680.75 5893350.85 12-4-2011 239.2 2473.4
100/01-26-048-05W5/0 658908.90 5893305.56 2-24-2012 10.5 1142.2
100/10-26-048-05W5/0 660013.05 5894087.49 10-15-2012 297.6 2205.1
100/11-26-048-05W5/0 658225.85 5894770.95 3-3-2013 253.0 1706.5
102/14-26-048-05W5/0 658217.61 5895081.71 3-11-2013 114.2 743.0
100/02-27-048-05W5/0 657808.84 5893356.46 2-14-2012 13.8 1239.4
100/08-28-048-05W5/0 655436.39 5893667.25 11-9-2009 547.2 1019.6
100/04-29-048-05W5/0 654035.46 5893161.68 6-24-2011 284.9 1150.6
100/05-29-048-05W5/0 654024.28 5893363.40 3-8-2011 659.3 1392.1
100/12-29-048-05W5/0 654006.88 5894009.36 6-13-2011 659.3 1925.0
100/13-29-048-05W5/0 653998.52 5894219.01 6-1-2011 270.2 1485.6
100/04-30-048-05W5/0 652391.83 5893415.03 3-13-2011 915.0 2033.4
100/05-30-048-05W5/0 652406.62 5893616.46 9-13-2010 1211.4 2453.2
100/11-30-048-05W5/0 651946.85 5894685.19 8-22-2011 1101.3 2542.0
100/12-30-048-05W5/0 651650.96 5894683.81 8-27-2012 708.4 2369.5
167
100/13-32-048-05W5/0 653906.21 5895924.83 8-29-2009 477.0 1058.0
100/09-34-048-05W5/0 657048.35 5895426.44 11-30-2011 88.3 1322.4
100/01-35-048-05W5/0 659489.55 5895451.30 1-10-2012 371.7 1360.6
102/01-35-048-05W5/0 658476.63 5895188.97 3-20-2013 28.7 1278.5
100/04-36-048-05W5/0 660657.64 5894868.35 11-11-2012 491.4 2439.0
100/05-36-048-05W5/0 659874.69 5894728.48 7-26-2011 777.4 2707.0
100/12-36-048-05W5/0 660550.38 5895635.14 11-29-2012 630.8 2014.6
102/13-14-048-06W5/0 648201.77 5890299.48 2-9-2011 515.1 975.8
102/14-14-048-06W5/0 648474.96 5890231.66 2-24-2011 451.2 867.0
100/03-17-048-06W5/0 643988.78 5890310.11 2-10-2013 356.3 1909.3
100/09-19-048-06W5/0 642621.17 5891958.29 6-16-2012 331.8 866.1
100/15-19-048-06W5/0 643378.23 5893220.89 3-8-2011 67.7 329.3
102/02-21-048-06W5/0 647132.72 5891504.33 9-20-2011 422.8 993.0
100/15-23-048-06W5/0 648725.15 5892131.28 10-1-2011 363.4 1260.3
100/05-27-048-06W5/0 647483.89 5892524.54 10-7-2012 185.7 1787.1
100/13-27-048-06W5/0 647477.76 5893392.62 9-25-2012 876.3 2538.9
100/09-28-048-06W5/0 647354.36 5893238.82 9-15-2012 787.1 3033.9
102/13-30-048-06W5/0 641959.76 5893024.64 6-8-2012 169.9 993.3
100/07-31-048-06W5/0 643424.57 5894444.04 6-27-2012 189.1 861.1
100/09-31-048-06W5/0 643632.71 5894569.11 7-6-2012 43.9 361.6
103/16-33-048-06W5/0 646435.95 5894974.82 1-22-2012 1200.6 2218.8
100/16-34-048-06W5/0 647130.19 5895886.00 7-26-2011 0.0 448.4
100/13-35-048-06W5/0 648992.65 5895843.54 7-19-2010 24.7 365.5
100/08-36-048-06W5/0 650508.76 5894944.02 6-6-2010 170.0 389.2
100/03-01-048-07W5/0 639959.04 5886161.77 1-9-2013 532.1 1708.1
102/03-01-048-07W5/0 639954.52 5886319.10 1-20-2013 934.8 2776.8
102/06-01-048-07W5/0 639950.25 5886474.49 2-1-2013 111.6 913.5
102/12-05-048-07W5/2 634475.43 5886881.01 11-9-2000 37.4 142.2
100/13-06-048-07W5/3 632339.59 5887351.55 10-22-2000 1.5 186.5
102/01-07-048-07W5/0 634344.86 5888435.31 11-30-2010 108.2 376.8
100/03-07-048-07W5/3 632921.40 5887639.53 10-10-2000 63.2 299.6
102/12-07-048-07W5/2 632329.53 5887963.98 7-9-1993 161.5 581.5
100/09-09-048-07W5/0 636217.30 5888478.51 10-10-2010 66.2 961.6
102/12-09-048-07W5/2 635591.09 5888034.53 12-1-1992 48.3 407.4
100/16-09-048-07W5/0 636200.97 5888768.74 10-23-2010 158.3 1189.6
168
100/01-10-048-07W5/0 638372.85 5888534.68 6-21-2012 1951.9 3488.3
100/03-16-048-07W5/0 635522.64 5889247.17 9-3-2011 16.7 592.5
102/06-16-048-07W5/0 635248.03 5889597.81 11-4-2010 588.1 1868.2
102/10-16-048-07W5/0 636703.35 5890769.28 3-29-2011 328.5 1307.5
100/07-18-048-07W5/0 633750.12 5889444.69 12-11-2010 81.2 433.8
102/02-21-048-07W5/0 635589.32 5890923.38 9-19-2010 91.2 1804.2
102/10-21-048-07W5/0 637094.43 5892568.75 4-9-2012 88.6 792.4
100/01-27-048-07W5/0 637804.67 5892115.54 3-19-2011 82.6 508.1
100/05-27-048-07W5/0 637420.29 5893500.09 3-28-2009 0.0 1414.8
103/05-27-048-07W5/0 636525.07 5892574.20 11-2-2012 43.8 1128.4
100/03-28-048-07W5/0 635290.27 5891689.12 9-7-2010 365.1 1331.7
100/05-34-048-07W5/0 637469.60 5894215.65 3-9-2009 1241.0 3266.8
100/15-34-048-07W5/0 637934.35 5894622.26 3-25-2010 15.2 2100.4
100/13-35-048-07W5/0 639353.66 5896135.15 3-29-2011 353.9 834.8
102/04-07-048-08W5/2 622439.07 5888680.84 7-27-2012 1037.5 2927.9
100/07-19-048-08W5/0 624375.28 5891130.15 12-13-2011 88.9 718.9
100/13-19-048-08W5/0 623149.21 5892150.05 10-24-2011 309.0 1308.8
102/12-20-048-08W5/0 624636.26 5891623.17 9-20-2011 440.9 1080.2
100/13-21-048-08W5/0 626375.95 5892045.03 9-14-2010 340.5 1222.7
102/13-21-048-08W5/0 626428.11 5891705.76 7-30-2011 274.9 1761.9
103/06-22-048-08W5/0 626692.16 5891201.44 9-5-2012 179.6 2997.2
102/13-22-048-08W5/0 627495.10 5891656.53 11-16-2009 1.0 1.0
100/15-22-048-08W5/0 627683.83 5892075.02 9-29-2010 187.5 662.9
102/09-26-048-08W5/0 629211.82 5893159.22 10-19-2011 178.6 657.8
100/03-27-048-08W5/0 627110.19 5892352.78 1-18-2010 700.6 2960.7
103/06-27-048-08W5/0 627060.67 5892883.51 7-10-2010 623.6 1863.0
100/11-27-048-08W5/0 627052.25 5893151.65 12-7-2009 113.1 1504.4
105/14-27-048-08W5/0 627040.58 5893618.60 9-18-2010 627.9 2781.9
100/04-28-048-08W5/0 626136.49 5892350.77 1-17-2012 171.9 2235.9
100/05-28-048-08W5/0 626118.19 5892825.57 3-29-2011 974.4 3412.0
100/12-28-048-08W5/0 624976.52 5893239.98 7-14-2011 281.6 511.4
100/13-28-048-08W5/0 624984.96 5893515.96 6-24-2011 177.3 2067.4
102/04-29-048-08W5/0 624720.56 5892367.27 1-17-2011 292.7 1499.5
100/05-29-048-08W5/0 624776.78 5892827.75 9-5-2010 130.1 1866.7
102/04-30-048-08W5/0 623074.57 5892359.48 1-20-2011 701.1 2096.6
169
103/05-30-048-08W5/0 623115.73 5892749.38 10-15-2010 243.5 2027.6
102/10-30-048-08W5/0 623686.16 5893228.70 7-4-2011 497.5 1602.4
100/15-30-048-08W5/0 623694.88 5893477.02 6-13-2011 651.0 817.1
100/01-31-048-08W5/0 622745.47 5893907.48 1-3-2011 620.5 1901.6
103/08-31-048-08W5/0 622767.69 5894349.46 9-2-2011 375.7 1045.9
100/09-31-048-08W5/0 622739.15 5894827.34 3-13-2011 275.9 1381.5
103/16-31-048-08W5/0 622652.01 5895026.77 6-3-2011 317.0 2451.2
102/04-32-048-08W5/0 624653.11 5894029.88 8-23-2012 305.0 1557.5
100/05-32-048-08W5/0 624648.10 5894221.97 8-13-2012 152.9 1711.9
100/09-32-048-08W5/0 624639.95 5894643.48 11-14-2012 98.7 1480.6
100/01-33-048-08W5/0 626070.80 5893964.44 8-6-2010 452.9 2096.0
100/09-33-048-08W5/0 625993.92 5894891.32 3-28-2011 710.3 2903.5
102/04-34-048-08W5/0 627221.49 5894710.50 1-17-2013 50.7 1149.2
102/05-35-048-08W5/0 628583.47 5893862.69 3-29-2012 43.7 615.2
102/08-22-048-09W5/0 618599.00 5890692.15 2-26-2002 69.7 122.0
102/09-22-048-09W5/0 618516.85 5890888.83 8-14-2001 704.7 2409.3
100/15-22-048-09W5/0 618205.64 5891436.79 3-30-2002 261.2 775.9
102/02-24-048-09W5/0 621759.22 5891389.26 1-8-2012 300.1 1906.3
102/04-04-049-04W5/0 665419.34 5896685.98 8-18-2012 28.0 767.9
100/13-04-049-04W5/0 664591.72 5897339.89 10-5-2012 43.5 1663.5
100/04-05-049-04W5/0 663791.54 5896634.46 9-27-2012 20.4 910.6
100/12-05-049-04W5/0 662862.88 5898158.99 10-11-2011 384.6 1339.2
102/12-05-049-04W5/0 663082.31 5898167.37 7-25-2012 65.6 1155.9
100/15-05-049-04W5/0 664167.69 5897346.47 9-21-2012 743.2 2420.9
102/16-05-049-04W5/0 664450.54 5897364.93 9-14-2012 140.2 949.2
102/08-06-049-04W5/0 662003.77 5896982.24 1-30-2013 44.8 301.5
102/02-08-049-04W5/0 664534.50 5898385.95 5-17-2012 60.9 591.1
100/09-08-049-04W5/0 663613.55 5898987.86 10-4-2011 12.4 583.6
100/04-01-049-05W5/0 660521.79 5896311.59 1-18-2013 429.6 3081.3
102/05-01-049-05W5/0 660504.37 5896924.79 2-9-2013 305.1 2180.2
100/12-03-049-05W5/0 657036.37 5896483.67 4-19-2013 1232.4 4751.4
100/10-04-049-05W5/0 656789.82 5896478.67 4-10-2013 716.9 3416.0
100/11-04-049-05W5/0 656488.44 5896485.45 4-1-2013 880.7 4265.6
100/12-05-049-05W5/0 654072.23 5897397.67 11-27-2012 78.3 1166.5
100/01-07-049-05W5/0 651699.11 5897947.70 7-25-2010 856.7 3450.7
170
102/04-08-049-05W5/0 653987.71 5897895.35 12-8-2012 493.3 2029.9
100/01-11-049-05W5/0 659051.01 5898278.43 3-7-2010 88.2 401.2
102/06-01-049-06W5/0 649627.50 5896598.62 10-18-2011 7.2 681.4
100/07-01-049-06W5/0 651070.77 5896509.34 3-5-2010 305.3 691.5
100/10-01-049-06W5/0 652040.74 5897245.85 12-17-2011 887.9 2809.1
100/12-02-049-06W5/0 648947.78 5896976.38 11-25-2010 117.4 1391.9
102/12-02-049-06W5/0 647229.61 5896959.83 2-19-2011 741.7 1775.3
100/13-02-049-06W5/0 648939.87 5897577.99 9-14-2010 1029.2 2314.0
100/03-03-049-06W5/0 646297.46 5896339.53 1-27-2011 365.3 789.7
100/06-03-049-06W5/0 646295.29 5896518.48 8-14-2010 1059.1 2505.0
100/07-03-049-06W5/0 648111.81 5896581.55 10-8-2011 128.7 683.9
100/16-03-049-06W5/0 647171.47 5897522.20 7-18-2011 101.6 1289.7
100/03-04-049-06W5/0 644704.21 5896427.37 2-9-2013 1513.9 4296.0
102/06-04-049-06W5/0 644703.33 5896626.23 2-18-2013 82.3 1475.3
100/03-05-049-06W5/0 643189.61 5895432.72 3-14-2011 463.5 1738.9
100/01-06-049-06W5/0 642746.47 5895499.23 8-21-2011 60.5 200.5
100/07-06-049-06W5/0 643191.82 5896578.72 1-29-2013 230.7 1203.9
100/05-09-049-06W5/0 645831.38 5898367.34 3-25-2010 160.1 393.3
100/12-09-049-06W5/0 645776.90 5898618.63 10-18-2010 158.0 676.3
100/13-09-049-06W5/0 645764.20 5898799.93 10-2-2010 16.5 640.7
100/08-10-049-06W5/0 647394.75 5898393.89 7-18-2011 663.8 1947.8
100/10-10-049-06W5/0 647876.42 5898559.73 11-15-2010 1086.2 3823.2
100/04-12-049-06W5/0 650307.57 5897905.81 8-3-2010 909.9 3259.2
100/11-12-049-06W5/0 649479.76 5898605.90 11-6-2010 460.0 2426.0
102/04-15-049-06W5/0 646259.80 5900222.23 10-28-2012 578.6 3816.3
103/04-15-049-06W5/0 647504.71 5899409.34 11-17-2012 375.0 3989.2
100/10-16-049-06W5/0 645728.79 5899674.56 11-15-2010 0.0 810.2
100/13-16-049-06W5/0 645008.02 5899805.07 10-31-2010 0.0 734.8
100/04-17-049-06W5/0 643955.27 5899532.35 9-5-2010 39.6 1282.8
100/05-17-049-06W5/0 643965.40 5899816.64 1-27-2010 591.3 1494.2
100/13-17-049-06W5/0 643616.54 5900253.28 7-2-2010 588.0 1446.8
100/13-18-049-06W5/0 642327.44 5900476.31 1-15-2010 271.1 666.7
100/07-19-049-06W5/0 642735.25 5900902.96 8-1-2009 707.0 1522.0
100/10-19-049-06W5/0 642850.31 5901713.97 2-28-2011 728.0 2025.7
100/04-20-049-06W5/0 643296.32 5901324.38 2-19-2011 490.1 2296.3
171
100/07-20-049-06W5/0 644346.91 5900594.54 3-6-2012 200.5 1432.6
100/09-20-049-06W5/0 644614.11 5900699.09 3-17-2012 99.9 1158.2
102/01-21-049-06W5/0 645311.27 5901009.84 10-19-2012 133.9 2035.0
100/09-25-049-06W5/0 650006.69 5903833.30 7-12-2013 111.7 2474.8
102/16-25-049-06W5/0 649979.72 5904224.35 7-21-2013 68.0 2515.5
102/04-30-049-06W5/0 642442.99 5902542.06 11-6-2012 423.6 3879.1
100/05-31-049-06W5/0 641904.53 5904082.90 8-24-2010 126.6 546.3
102/16-01-049-07W5/0 640768.77 5896998.45 4-10-2011 27.5 154.8
102/12-10-049-07W5/0 636120.48 5897343.76 4-24-2012 48.6 374.6
100/09-22-049-07W5/0 637293.42 5901492.91 3-24-2011 810.2 2876.5
102/16-22-049-07W5/0 637450.96 5902003.21 2-8-2010 774.2 1802.3
100/02-23-049-07W5/0 639069.63 5901994.28 7-14-2011 169.7 1909.3
100/12-23-049-07W5/0 638483.44 5902296.59 10-15-2010 651.0 2485.6
100/01-24-049-07W5/0 640893.24 5901629.19 11-17-2011 5.9 1847.0
103/03-24-049-07W5/0 640580.30 5901617.43 11-5-2011 19.2 915.0
100/01-27-049-07W5/0 637173.77 5902563.76 1-9-2011 1073.1 2442.2
103/08-27-049-07W5/0 637151.66 5902795.00 12-19-2010 784.8 2383.7
100/09-27-049-07W5/0 637396.93 5903276.26 8-17-2011 631.4 2314.1
103/16-27-049-07W5/0 637401.83 5903560.94 8-30-2011 684.2 1455.7
100/01-28-049-07W5/0 636443.71 5902826.77 8-4-2011 191.1 1161.4
100/12-28-049-07W5/0 635842.83 5903217.15 10-26-2010 0.0 3136.6
100/13-28-049-07W5/0 635851.44 5903499.86 2-24-2010 778.3 1945.3
102/16-31-049-07W5/0 632909.38 5904399.98 12-12-2010 639.6 1913.0
100/15-34-049-07W5/0 637567.82 5904184.55 3-1-2013 91.0 1498.1
102/15-34-049-07W5/0 638515.63 5905193.74 6-19-2013 462.1 998.6
102/16-34-049-07W5/0 637787.87 5904192.74 2-20-2013 18.2 340.2
100/01-35-049-07W5/0 639138.16 5903519.60 7-23-2011 37.7 943.4
102/04-04-049-08W5/0 626322.83 5895508.47 1-8-2013 238.2 1826.7
100/04-13-049-09W5/0 621349.70 5898586.63 11-4-2010 1468.6 3731.1
100/05-13-049-09W5/0 621352.86 5899150.46 2-2-2011 996.4 2605.3
103/02-24-049-09W5/0 622151.17 5900201.21 8-14-2011 76.3 1488.1
100/10-33-049-09W5/0 617216.52 5904227.17 1-23-2013 217.5 1321.3
100/13-10-050-07W5/0 636289.47 5907966.21 10-16-2003 0.0 46.9
100/07-15-050-07W5/0 637078.27 5908770.42 2-16-2005 64.6 266.6
100/01-10-050-09W5/0 617564.24 5906783.49 1-22-2012 0.0 1220.9
102/08-10-050-09W5/0 617553.06 5907053.68 1-30-2012 0.0 1213.7
100/09-10-050-09W5/0 617542.55 5907279.19 2-8-2012 0.0 1581.6
172
UWI
6 month
cumulative
oil (m3)
1 year
cumulativ
e oil (m3)
1st month
average (m3)
3rd month
average (m3)
1 year
average
(m3)
Bioturbated
Facies
geometric
mean (mD)
Sandstone
Thickness
(m)
Play Type
(Halo = 1,
Perm = 2)
100/16-14-047-05W5/0 1988.1 2692 22.47537012 9.459217877 3.23448276 0.475214377 0 1
100/13-16-047-05W5/0 2509.5 3371.1 27.78983051 9.522362869 5.71451613 0.487331464 0 1
100/16-17-047-05W5/0 3994.7 5094.6 58.55067961 20.3534626 7.80625 0.488135668 0 1
102/05-19-047-05W5/0 2610 3251.7 65.21142857 23.26676602 6.05935484 0.491757856 0 1
100/13-19-047-05W5/0 3327.3 5158.9 26.79864407 17.88333333 10.0158254 0.504272962 0 1
100/05-20-047-05W5/0 3288.7 5165.7 25.55333333 17.28666667 8.99916551 0.493273293 0 1
100/16-20-047-05W5/0 1360.8 2120.4 15.09839228 7.602292264 3.66451613 0.4994475 0 1
100/04-21-047-05W5/0 3225.8 4525.6 32.89700272 18.27419355 9.07687776 0.486285372 0 1
100/05-21-047-05W5/0 1523.5 2198.2 20.37391304 11.87172996 4.17096774 0.485249273 0 1
100/09-21-047-05W5/0 1724.7 2458.4 15.1160221 9.444952894 2.05810056 0.48501807 0 1
100/14-22-047-05W5/0 763.2 1131.8 8.454355401 3.6 2.50322581 0.471314376 0 1
100/13-26-047-05W5/0 2543.7 4506.7 60.57263158 18.14516129 11.5740845 0.42545456 0 1
100/14-26-047-05W5/0 2410.6 4262.2 60.58947368 15.55806452 7.70379009 0.42512798 0 1
103/08-27-047-05W5/0 1133.5 1681.7 9.729032258 6.470967742 2.64666667 0.442126453 0 1
100/16-27-047-05W5/0 1642.3 2487 12.54285714 9.1 4.18387097 0.417671624 0 1
100/13-28-047-05W5/0 3374.5 27.58360656 20.4 0.482775789 0 1
100/14-28-047-05W5/0 3414.9 25.58387097 20.43571429 0.477742587 0 1
100/15-28-047-05W5/0 2537.4 3522.4 23.5516129 8.75862069 4.31333333 0.458879878 0 1
102/16-28-047-05W5/0 1956.2 2886.9 17.07419355 10.22 4.13371105 0.453347313 0 1
100/12-29-047-05W5/0 3131 46.88571429 19.66914378 0.499684804 0.010333906 1
102/12-29-047-05W5/0 2683.5 43.17142857 20.89968454 0.499472924 0 1
100/13-29-047-05W5/0 3115.5 46.67142857 18.06552901 0.499878221 0.011966327 1
102/14-29-047-05W5/0 1887.5 2854.9 16.75154778 9.756948229 4.67142857 0.497780442 0.014253981 1
100/01-34-047-05W5/0 3509.5 5007.2 34.08648649 18.72391304 9.19751553 0.393826783 0 1
102/01-34-047-05W5/0 23.28071217 25.50645161 0.394471879 0 1
100/02-34-047-05W5/0 4891.9 6564.7 62.61098901 23.10326087 9.65915493 0.394877783 0 1
100/03-34-047-05W5/0 5885.3 26.49842271 27.53099042 0.396176321 0 1
100/12-24-047-06W5/0 1649.7 2547.8 14.18064516 11.38924731 4.64583942 0.485995166 0 1
100/04-25-047-06W5/0 1697.1 2419.7 16.76887608 8.206451613 5.69354839 0.509614015 0 1
100/05-25-047-06W5/0 1267.2 1908.3 13.05882353 7.921428571 2.60933063 0.5207043 0 1
100/13-30-047-06W5/0 2942.9 4053.8 38.97797357 12.73687231 5.17857143 0.475448567 1.357749982 1
102/16-24-047-07W5/0 1243.3 9.318181818 6.890322581 0.719919907 3.123998276 1
102/03-25-047-07W5/0 38.31864407 0.456941294 2.088723154 1
102/04-25-047-07W5/0 146.8 275 2.260227273 0.395652174 1.10333333 0.445423145 1.891923606 1
103/04-25-047-07W5/0 26.77361478 0.453107734 2.254885703 1
100/15-25-047-07W5/0 4059.3 5748.6 38.0862069 24.46129032 7.57997294 0.456949391 1.684697205 1
102/16-25-047-07W5/0 2561.8 23.54219653 14.73214286 0.479573611 1.58405176 1
102/10-26-047-07W5/0 36.68242812 0.49 2.351538815 1
102/09-27-047-07W5/0 2005 2404 20.69662921 15.31 2.29195089 0.438485413 5.192204249 1
100/09-29-047-07W5/0 938.7 2849.5 0.86 7.681818182 7.6 0.398598245 6.105575702 1
102/07-33-047-07W5/0 1205.9 1323.9 21.13271028 3.256666667 1.0313779 0.371528412 6.391040276 1
102/14-22-047-09W5/0 293 466.1 0.265517241 1.853846154 0.93333333 1.087187912 4.347395938 1
100/15-22-047-09W5/0 418.7 722.2 3.580645161 2.75483871 1.84 1.082374576 4.39475596 1
100/10-28-047-09W5/0 2489.4 4085.8 12.95 13.31935484 7.61666667 1.156025975 3.804187522 1
103/14-28-047-09W5/0 11.58333333 3.215384615 1.159326759 3.757672093 1
100/01-04-048-04W5/0 186.1 0.513772455 0.896666667 0.63941222 0.001896373 2
100/13-07-048-04W5/0 2765.3 19.4 20.80248447 0.628585611 0.086872007 2
100/01-16-048-04W5/0 1501 2274.4 16.32068966 7.085878963 3.50322581 0.755355435 0.455828463 2
100/08-16-048-04W5/0 2138.3 3094.5 20.86451613 10.63333333 4.17 0.7697553 0.674175084 2
100/09-16-048-04W5/0 3300.6 4966.6 26.18601399 19.01899441 6.66702557 0.864804789 0.838711711 2
100/06-17-048-04W5/0 1136.3 1766.7 9.241791045 6.216129032 2.67 0.7618036 0.518372886 2
100/13-17-048-04W5/0 2612.1 4352.2 24.65869565 13.89932705 6.6 0.89210202 0.74718309 2
100/04-18-048-04W5/0 1205.7 2035.3 16.53636364 3.89333333 0.707494222 0.179436847 2
100/05-18-048-04W5/0 1792.6 3065.6 35.15454545 5.66666667 0.736848004 0.210359685 2
173
100/12-18-048-04W5/2 3155.2 3993 35.38181818 17.86129032 3.04333333 0.765546048 0.240360905 2
100/13-18-048-04W5/0 2388.7 3014.5 31.34285714 13.65483871 3.37666667 0.802152631 0.280487358 2
100/04-19-048-04W5/0 3047.2 4514.5 29.56451613 18.63243243 7.88064516 0.955953672 0.375255538 2
100/05-19-048-04W5/0 4631.2 6610.4 33.79013453 29.83368107 6.93666667 1.015381881 0.415216295 2
100/12-19-048-04W5/0 5133 8475.2 29.52067039 28.09944134 12.3197847 1.152753504 0.501745414 2
100/13-19-048-04W5/0 5098.2 9113.3 21.66575342 33.89869754 20.0326531 1.250657815 0.566016602 2
100/01-20-048-04W5/0 4625.4 6407.1 43.75489362 24.14516129 7.18064516 0.981217682 0.813768563 2
102/08-20-048-04W5/0 4711.2 7427.9 5.033333333 34.72225352 7.94366197 1.049008612 0.864943733 2
102/09-20-048-04W5/0 2956.4 5041.2 5.493484419 17.28539326 8.98709677 1.147995961 0.952097807 2
100/01-21-048-04W5/0 3775.3 5125.2 28.43353293 23.73843888 5.74643338 1.045284598 0.914218606 2
100/12-21-048-04W5/0 600.8 6.130820996 3.614906832 1.619999448 1.153841957 2
100/13-21-048-04W5/0 3647.8 5733.5 20.91055901 24.48488372 10.8500673 1.224578726 1.028287524 2
100/01-28-048-04W5/0 8.899378882 4.042105263 1.540612927 1.221717201 2
100/04-29-048-04W5/0 11.04596273 5.405668016 1.235712581 0.980982821 2
102/04-29-048-04W5/0 20.48944099 10.17004049 1.26702541 0.976259749 2
100/01-30-048-04W5/0 3896.1 5676.1 37.51219512 21.6483871 7.71958763 1.413633524 0.641543745 2
100/09-30-048-04W5/0 3083.9 37.88181818 23.21769912 1.549699709 0.725028699 2
100/01-31-048-04W5/0 747.4 10.72698908 2.916861436 1.407675569 0.863570733 2
100/09-31-048-04W5/0 509.7 5.558130841 3.26111869 1.241386888 0.928292184 2
103/12-33-048-04W5/0 1723.2 3029.2 14.3035868 9.398373984 6.85395349 1.548689102 0.812018644 2
102/13-33-048-04W5/0 4140.3 5580.8 31.28263989 29.43414634 8.17488372 1.553280054 0.764494063 2
103/13-33-048-04W5/0 2833.8 27.38125 18.24456522 1.550654401 0.789083587 2
100/11-03-048-05W5/0 2514 19.29 15.52 0.377858407 0 1
100/16-03-048-05W5/0 1037.1 1525.8 11.62753036 5.158158996 2.27419355 0.367530893 0 1
100/13-09-048-05W5/0 965.9 1557.7 10.3137931 6.013186813 1.91612903 0.258001502 0 1
100/01-10-048-05W5/0 3449.4 4444.7 31.17988827 16.29913043 5.15226337 0.342560931 0 1
100/08-10-048-05W5/0 2546.7 3678.9 27.89318182 12.66434783 4.54979424 0.327520557 0 1
100/09-10-048-05W5/0 2689.2 3469.6 35.8683871 13.47692308 3.12324324 0.298268966 0 1
102/09-10-048-05W5/0 2934.5 3687.5 42.45204236 14.4383164 3.83351351 0.302243397 0 1
100/16-10-048-05W5/0 852 1332.9 9.533333333 4.703571429 2.3 0.302551722 0 1
100/08-13-048-05W5/0 1470 2228 13.75 8.11978022 3.43225806 0.588828299 0 1
100/13-13-048-05W5/0 4132.4 33.51071429 24.51333333 0.737627382 0.039377416 1
100/05-14-048-05W5/0 963.9 1483.3 9.121407625 5.261290323 2.42903226 0.450677353 0 1
102/16-15-048-05W5/0 636.9 989.6 4.526666667 3.158064516 1.79354839 0.332472608 0 1
102/01-16-048-05W5/0 2541 3501.2 27.53200613 14.25941423 3.7776435 0.3 0 1
100/08-16-048-05W5/0 2958.6 4513.1 24.56785714 22.4625 7.09288703 0.219254872 0 1
100/09-16-048-05W5/0 4159.8 6282.9 37.04718163 27.61669243 8.55225102 0.4 0 1
100/16-16-048-05W5/0 2814.8 3932.5 27.01956522 16.57095436 5.5373494 0.4 0 1
100/04-17-048-05W5/0 3095.4 3742.9 43.36977492 16.86898638 2.96391608 0.264482689 0 1
100/05-17-048-05W5/0 2362.7 2890.5 35.49259259 8.997557666 3.72507042 0.209138293 0 1
100/12-17-048-05W5/0 1657.4 2402.5 14.41666667 15.13125 4.68691099 0.127737387 0 1
100/13-17-048-05W5/0 1724.7 2343.9 17.63217753 10.76982592 3.69032258 0.180240676 0 1
100/07-18-048-05W5/0 1082.7 1752.6 8.78 6.313333333 4.13173653 0.729794496 0.089733096 1
100/12-18-048-05W5/0 1635.7 2506 16.03 8.513333333 3.86946108 0.584129513 0.072543396 1
102/14-18-048-05W5/0 469.1 635.4 5.419672131 2.432258065 1.56 0.462710041 0.006968331 1
102/04-19-048-05W5/0 1998.3 2570.7 25.94516129 9.561290323 1.90726257 0.467637251 0 1
100/08-19-048-05W5/0 1795.7 2528.6 20.31294452 9.4 2.94760563 0.412503982 0 1
102/08-19-048-05W5/0 996.4 14.81034483 3.013407821 0.421992725 0 1
100/09-19-048-05W5/0 897.7 1294.3 10.17614679 4.709677419 2.07596439 0.400966347 0 1
103/16-19-048-05W5/0 1562.4 2057.1 19.72298507 7.090322581 2.57545692 0.368049171 0 1
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103/13-21-048-05W5/0 1853.8 2534.8 16.00554017 11.02258065 2.99333333 0.324753644 0 1
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100/01-33-048-08W5/0 4170.1 6614.6 26.58151261 25.45352113 10.97 0.5 0.985103876 1
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177
100/13-17-049-06W5/0 2010.2 3230.6 15.76803395 11.36381487 6.01034483 0.460686234 0 1
100/13-18-049-06W5/0 930.2 1512.5 7.491428571 4.957264957 3.15908479 0.477926364 0 1
100/07-19-049-06W5/0 1905.9 3178.5 14.74333333 15.50723192 6.23140496 0.497011077 0 1
100/10-19-049-06W5/0 2023.4 2889.1 30.41025641 9.254545455 3.63333333 0.509698932 0.098800509 1
100/04-20-049-06W5/0 3347.9 4322.6 36.41666667 16.75568182 3.92 0.50887559 0.109212282 1
100/07-20-049-06W5/0 2478.8 3690.7 24.34758621 13.55865922 5.15666667 0.490589007 0.290477134 1
100/09-20-049-06W5/0 2546.4 3567.2 20.6 18.75 5.79159664 0.501425951 0.529277636 1
102/01-21-049-06W5/0 5066.4 33.06506024 32.53870968 0.546123622 1.313102593 1
100/09-25-049-06W5/0 51.40148148 0.517264605 0.758384179 1
102/16-25-049-06W5/0 57.9023622 0.488336008 0.653286377 1
102/04-30-049-06W5/0 7967.3 63.00647149 62.6881459 6.02857143 0.502684585 0.298825271 1
100/05-31-049-06W5/0 800 1497.1 8.431622746 4.806451613 3.33352192 0.689363692 1.240825156 1
102/16-01-049-07W5/0 426.8 701.9 2.947132867 1.46086957 0.617178117 2.940082095 1
102/12-10-049-07W5/0 1199.9 3586.1 6.431034483 6.419354839 12.3277533 0.903552182 4.40007412 1
100/09-22-049-07W5/0 6093.4 10650.2 38.5 35.26538462 34.1903226 0.750990888 0.754319756 1
102/16-22-049-07W5/0 2478.4 3699.2 18.19666667 14.72903226 5.55193133 0.750793282 0.59025408 1
100/02-23-049-07W5/0 4432 6282.9 23.57666667 35.29851632 6.90645161 0.653323022 0.129475842 1
100/12-23-049-07W5/0 3373.3 4634.7 36.88595041 16.22594595 3.7483871 0.696289948 0.257936563 1
100/01-24-049-07W5/0 3743.8 5079.4 27.61769912 22.59322034 5.90967742 0.561047349 0 1
103/03-24-049-07W5/0 1465.5 2133.2 20.77876106 6.949152542 2.82 0.572336724 0 1
100/01-27-049-07W5/0 4647.8 7511.5 33.136 31.10666667 11.0987887 0.787894117 0.67352894 1
103/08-27-049-07W5/0 3347.3 4896.4 30.98918919 25.359375 10.7113122 0.7955036 0.706857999 1
100/09-27-049-07W5/0 3074.9 4454.3 36.50169492 15.90659341 5.98709677 0.793358961 0.738615183 1
103/16-27-049-07W5/0 1682.1 2752.8 17.10375 8.482417582 5.49971831 0.800964096 0.835631769 1
100/01-28-049-07W5/0 4594 6124.2 11.75280899 35.0490566 4.94659091 0.852751653 0.922867135 1
100/12-28-049-07W5/0 6500.4 9058.6 58.8 38.20357143 13.1323944 0.90426847 0.95235456 1
100/13-28-049-07W5/0 2535.8 3674.4 26.552 14.09628611 5.14666667 0.900885437 1.227935482 1
102/16-31-049-07W5/0 2892.1 4432.2 26.43773585 15.74915254 6.58387097 0.90528 1.84024043 1
100/15-34-049-07W5/0 2764.3 28.425 18.03333333 0.810280996 1.109198816 1
102/15-34-049-07W5/0 18.5 0.825751027 1.739540114 1
102/16-34-049-07W5/0 1676.6 7.482352941 27.98666667 0.803466672 1.05562216 1
100/01-35-049-07W5/0 2195.1 3836.3 15.81 15.19330544 8.01926346 0.727978069 0.305453258 1
102/04-04-049-08W5/0 4731.4 17.27857143 25.96666667 0.713248198 5.111624181 1
100/04-13-049-09W5/0 5351.8 7903.9 41.075 20.71071429 13.7190184 1.145330087 2.229657873 2
100/05-13-049-09W5/0 3476.2 5017 27.67725322 20.26451613 7.18965517 1.115041381 2.379297514 2
103/02-24-049-09W5/0 3000.2 4537.8 25.74339623 17.41666667 6.75862069 0.951542353 2.586114188 2
100/10-33-049-09W5/0 3188.2 28.356 21.48813559 0.865084883 0.70909725 2
100/13-10-050-07W5/0 244.6 901.7 1.288888889 1.05483871 2.90967742 0.549804663 5.525720406 1
100/07-15-050-07W5/0 464.4 860.5 3.583333333 2.72 2.02333333 0.389272449 6.434176958 1
100/01-10-050-09W5/0 2267.2 3199.2 27.46191248 10.60322581 4.2 0.355493249 0 1
102/08-10-050-09W5/0 2082.4 2770.2 25.81290323 9.667741935 2.70530035 0.333554255 0 1
100/09-10-050-09W5/0 3021.1 3941.9 26.14193548 17.2516129 4.60666667 0.313477635 0 1