- Abstract
- Affiliation
- All
- Authors
- Book Series
- DOI
- EISBN
- EISSN
- Full Text
- GeoRef ID
- ISBN
- ISSN
- Issue
- Keyword (GeoRef Descriptor)
- Meeting Information
- Report #
- Title
- Volume
- Abstract
- Affiliation
- All
- Authors
- Book Series
- DOI
- EISBN
- EISSN
- Full Text
- GeoRef ID
- ISBN
- ISSN
- Issue
- Keyword (GeoRef Descriptor)
- Meeting Information
- Report #
- Title
- Volume
- Abstract
- Affiliation
- All
- Authors
- Book Series
- DOI
- EISBN
- EISSN
- Full Text
- GeoRef ID
- ISBN
- ISSN
- Issue
- Keyword (GeoRef Descriptor)
- Meeting Information
- Report #
- Title
- Volume
- Abstract
- Affiliation
- All
- Authors
- Book Series
- DOI
- EISBN
- EISSN
- Full Text
- GeoRef ID
- ISBN
- ISSN
- Issue
- Keyword (GeoRef Descriptor)
- Meeting Information
- Report #
- Title
- Volume
- Abstract
- Affiliation
- All
- Authors
- Book Series
- DOI
- EISBN
- EISSN
- Full Text
- GeoRef ID
- ISBN
- ISSN
- Issue
- Keyword (GeoRef Descriptor)
- Meeting Information
- Report #
- Title
- Volume
- Abstract
- Affiliation
- All
- Authors
- Book Series
- DOI
- EISBN
- EISSN
- Full Text
- GeoRef ID
- ISBN
- ISSN
- Issue
- Keyword (GeoRef Descriptor)
- Meeting Information
- Report #
- Title
- Volume
NARROW
GeoRef Subject
-
all geography including DSDP/ODP Sites and Legs
-
Atlantic Ocean
-
North Atlantic
-
Great Bahama Bank (2)
-
Gulf of Mexico
-
Florida Bay (1)
-
-
Little Bahama Bank (1)
-
Tongue of the Ocean (1)
-
-
-
Caribbean region
-
West Indies
-
Antilles
-
Greater Antilles
-
Hispaniola
-
Dominican Republic (1)
-
-
-
-
Bahamas (5)
-
-
-
Central America
-
Belize (1)
-
-
Europe
-
Southern Europe
-
Iberian Peninsula
-
Spain (1)
-
-
Italy (1)
-
-
Western Europe
-
Ireland
-
Dublin Ireland (1)
-
-
-
-
Front Range (1)
-
North America
-
Michigan Basin (17)
-
Rocky Mountains
-
U. S. Rocky Mountains
-
San Juan Mountains (1)
-
-
-
-
San Juan Basin (1)
-
South America
-
Argentina
-
Neuquen Basin (1)
-
-
-
United States
-
Anadarko Basin (7)
-
Arkansas
-
Benton County Arkansas (2)
-
Boone County Arkansas (2)
-
-
Arkoma Basin (2)
-
Bighorn Basin (1)
-
Cherokee Basin (5)
-
Colorado
-
San Juan volcanic field (1)
-
-
Illinois (1)
-
Indiana (1)
-
Iowa (1)
-
Kansas
-
Cherokee County Kansas (1)
-
Comanche County Kansas (1)
-
Harper County Kansas (1)
-
Osage County Kansas (1)
-
Reno County Kansas (2)
-
Sedgwick Basin (1)
-
-
Michigan
-
Michigan Lower Peninsula
-
Branch County Michigan (1)
-
Ionia County Michigan (1)
-
Macomb County Michigan (2)
-
Otsego County Michigan (2)
-
Wayne County Michigan (1)
-
-
-
Midcontinent (11)
-
Mississippi Valley (1)
-
Missouri
-
Jasper County Missouri (1)
-
McDonald County Missouri (2)
-
Stone County Missouri (3)
-
-
Ohio (1)
-
Oklahoma
-
Alfalfa County Oklahoma (1)
-
Blaine County Oklahoma (1)
-
Delaware County Oklahoma (2)
-
Garfield County Oklahoma (1)
-
Kay County Oklahoma (2)
-
Logan County Oklahoma (4)
-
Mayes County Oklahoma (3)
-
Noble County Oklahoma (1)
-
Oklahoma County Oklahoma (1)
-
Osage County Oklahoma (6)
-
Pawnee County Oklahoma (1)
-
Payne County Oklahoma (4)
-
Wagoner County Oklahoma (1)
-
Woods County Oklahoma (2)
-
-
Ozark Mountains (8)
-
Paradox Basin (1)
-
U. S. Rocky Mountains
-
San Juan Mountains (1)
-
-
Wabash Valley (1)
-
Wyoming (1)
-
-
Wind River basin (1)
-
-
commodities
-
brines (1)
-
oil and gas fields (7)
-
petroleum
-
natural gas (14)
-
-
tight sands (1)
-
-
elements, isotopes
-
carbon
-
C-13/C-12 (6)
-
-
isotope ratios (7)
-
isotopes
-
stable isotopes
-
C-13/C-12 (6)
-
O-18/O-16 (7)
-
Sr-87/Sr-86 (2)
-
-
-
metals
-
alkali metals
-
potassium (1)
-
-
alkaline earth metals
-
magnesium (1)
-
strontium
-
Sr-87/Sr-86 (2)
-
-
-
aluminum (1)
-
molybdenum (1)
-
nickel (1)
-
-
oxygen
-
O-18/O-16 (7)
-
-
silicon (1)
-
-
fossils
-
Chordata
-
Vertebrata
-
Tetrapoda
-
Mammalia (1)
-
-
-
-
Invertebrata
-
Arthropoda
-
Mandibulata
-
Crustacea
-
Ostracoda (1)
-
-
-
-
Brachiopoda (3)
-
Bryozoa (4)
-
Cnidaria
-
Anthozoa
-
Zoantharia
-
Rugosa (1)
-
Tabulata (1)
-
-
-
-
Echinodermata
-
Crinozoa
-
Crinoidea (5)
-
-
-
Mollusca
-
Gastropoda (2)
-
-
Porifera
-
Stromatoporoidea (1)
-
-
-
microfossils
-
Conodonta (4)
-
-
palynomorphs
-
miospores
-
pollen (1)
-
-
-
Plantae
-
algae
-
Rhodophyta
-
Corallinaceae (1)
-
-
-
-
-
geochronology methods
-
paleomagnetism (2)
-
-
geologic age
-
Cenozoic
-
Quaternary
-
upper Quaternary
-
Brunhes Chron (1)
-
-
-
Tertiary
-
Neogene
-
Gilbert Chron (1)
-
Miocene
-
upper Miocene (2)
-
-
Pliocene
-
Gauss Chron (1)
-
lower Pliocene (1)
-
-
-
-
-
Laurentide ice sheet (1)
-
Mesozoic
-
Cretaceous
-
Mancos Shale (1)
-
-
Jurassic
-
Upper Jurassic (1)
-
-
Vaca Muerta Formation (1)
-
-
Paleozoic
-
Arbuckle Group (1)
-
Cambrian (2)
-
Carboniferous
-
Mississippian
-
Boone Formation (2)
-
Lower Mississippian
-
Osagian
-
Burlington Limestone (1)
-
Keokuk Limestone (2)
-
-
Tournaisian (1)
-
-
Madison Group (1)
-
Middle Mississippian
-
Visean (1)
-
-
Upper Mississippian
-
Chesterian (3)
-
Fayetteville Formation (2)
-
Meramecian (3)
-
-
-
Pennsylvanian
-
Lower Pennsylvanian (1)
-
Middle Pennsylvanian
-
Atokan (1)
-
-
Saginaw Formation (1)
-
-
-
Devonian
-
Middle Devonian
-
Dundee Limestone (1)
-
Sylvania Formation (1)
-
-
-
Ordovician
-
Middle Ordovician
-
Saint Peter Sandstone (1)
-
-
Upper Ordovician (1)
-
Utica Shale (1)
-
-
Permian (1)
-
Silurian
-
Bass Islands Dolomite (2)
-
Lower Silurian
-
Llandovery (1)
-
Wenlock (1)
-
-
Niagaran (5)
-
-
upper Paleozoic
-
Antrim Shale (1)
-
Kaskaskia Sequence (1)
-
-
Woodford Shale (2)
-
-
-
minerals
-
carbonates
-
aragonite (1)
-
calcite (1)
-
dolomite (1)
-
-
halides
-
chlorides
-
halite (1)
-
sylvite (1)
-
-
-
silicates
-
framework silicates
-
silica minerals
-
quartz (2)
-
-
-
-
sulfates
-
anhydrite (2)
-
gypsum (2)
-
-
-
Primary terms
-
Atlantic Ocean
-
North Atlantic
-
Great Bahama Bank (2)
-
Gulf of Mexico
-
Florida Bay (1)
-
-
Little Bahama Bank (1)
-
Tongue of the Ocean (1)
-
-
-
brines (1)
-
carbon
-
C-13/C-12 (6)
-
-
Caribbean region
-
West Indies
-
Antilles
-
Greater Antilles
-
Hispaniola
-
Dominican Republic (1)
-
-
-
-
Bahamas (5)
-
-
-
Cenozoic
-
Quaternary
-
upper Quaternary
-
Brunhes Chron (1)
-
-
-
Tertiary
-
Neogene
-
Gilbert Chron (1)
-
Miocene
-
upper Miocene (2)
-
-
Pliocene
-
Gauss Chron (1)
-
lower Pliocene (1)
-
-
-
-
-
Central America
-
Belize (1)
-
-
Chordata
-
Vertebrata
-
Tetrapoda
-
Mammalia (1)
-
-
-
-
continental slope (1)
-
crystal structure (1)
-
data processing (1)
-
diagenesis (19)
-
economic geology (1)
-
Europe
-
Southern Europe
-
Iberian Peninsula
-
Spain (1)
-
-
Italy (1)
-
-
Western Europe
-
Ireland
-
Dublin Ireland (1)
-
-
-
-
faults (1)
-
folds (2)
-
fractures (3)
-
geochemistry (2)
-
geomorphology (1)
-
geophysical methods (11)
-
glacial geology (1)
-
ground water (1)
-
hydrogeology (1)
-
inclusions
-
fluid inclusions (3)
-
-
Invertebrata
-
Arthropoda
-
Mandibulata
-
Crustacea
-
Ostracoda (1)
-
-
-
-
Brachiopoda (3)
-
Bryozoa (4)
-
Cnidaria
-
Anthozoa
-
Zoantharia
-
Rugosa (1)
-
Tabulata (1)
-
-
-
-
Echinodermata
-
Crinozoa
-
Crinoidea (5)
-
-
-
Mollusca
-
Gastropoda (2)
-
-
Porifera
-
Stromatoporoidea (1)
-
-
-
isotopes
-
stable isotopes
-
C-13/C-12 (6)
-
O-18/O-16 (7)
-
Sr-87/Sr-86 (2)
-
-
-
Mesozoic
-
Cretaceous
-
Mancos Shale (1)
-
-
Jurassic
-
Upper Jurassic (1)
-
-
Vaca Muerta Formation (1)
-
-
metals
-
alkali metals
-
potassium (1)
-
-
alkaline earth metals
-
magnesium (1)
-
strontium
-
Sr-87/Sr-86 (2)
-
-
-
aluminum (1)
-
molybdenum (1)
-
nickel (1)
-
-
metasomatism (1)
-
North America
-
Michigan Basin (17)
-
Rocky Mountains
-
U. S. Rocky Mountains
-
San Juan Mountains (1)
-
-
-
-
Ocean Drilling Program
-
Leg 166 (1)
-
-
oil and gas fields (7)
-
orogeny (1)
-
oxygen
-
O-18/O-16 (7)
-
-
paleoclimatology (1)
-
paleoecology (1)
-
paleogeography (4)
-
paleomagnetism (2)
-
Paleozoic
-
Arbuckle Group (1)
-
Cambrian (2)
-
Carboniferous
-
Mississippian
-
Boone Formation (2)
-
Lower Mississippian
-
Osagian
-
Burlington Limestone (1)
-
Keokuk Limestone (2)
-
-
Tournaisian (1)
-
-
Madison Group (1)
-
Middle Mississippian
-
Visean (1)
-
-
Upper Mississippian
-
Chesterian (3)
-
Fayetteville Formation (2)
-
Meramecian (3)
-
-
-
Pennsylvanian
-
Lower Pennsylvanian (1)
-
Middle Pennsylvanian
-
Atokan (1)
-
-
Saginaw Formation (1)
-
-
-
Devonian
-
Middle Devonian
-
Dundee Limestone (1)
-
Sylvania Formation (1)
-
-
-
Ordovician
-
Middle Ordovician
-
Saint Peter Sandstone (1)
-
-
Upper Ordovician (1)
-
Utica Shale (1)
-
-
Permian (1)
-
Silurian
-
Bass Islands Dolomite (2)
-
Lower Silurian
-
Llandovery (1)
-
Wenlock (1)
-
-
Niagaran (5)
-
-
upper Paleozoic
-
Antrim Shale (1)
-
Kaskaskia Sequence (1)
-
-
Woodford Shale (2)
-
-
palynomorphs
-
miospores
-
pollen (1)
-
-
-
paragenesis (1)
-
petroleum
-
natural gas (14)
-
-
Plantae
-
algae
-
Rhodophyta
-
Corallinaceae (1)
-
-
-
-
plate tectonics (1)
-
pollution (1)
-
reefs (5)
-
remote sensing (1)
-
rock mechanics (1)
-
sea water (1)
-
sea-level changes (2)
-
sedimentary rocks
-
carbonate rocks
-
dolostone (2)
-
grainstone (3)
-
limestone
-
microbialite (1)
-
-
packstone (3)
-
wackestone (2)
-
-
chemically precipitated rocks
-
chert (6)
-
evaporites (2)
-
-
clastic rocks
-
diatomite (2)
-
mudstone (7)
-
red beds (1)
-
sandstone (7)
-
shale (2)
-
siltstone (2)
-
-
coal (1)
-
-
sedimentary structures
-
bedding plane irregularities (1)
-
biogenic structures
-
stromatolites (1)
-
-
planar bedding structures
-
bedding (1)
-
cross-bedding (1)
-
laminations (1)
-
-
secondary structures
-
concretions (1)
-
-
-
sedimentation (3)
-
sediments
-
carbonate sediments (1)
-
clastic sediments
-
mud (1)
-
-
marine sediments (1)
-
-
silicon (1)
-
South America
-
Argentina
-
Neuquen Basin (1)
-
-
-
spectroscopy (1)
-
stratigraphy (8)
-
tectonics (3)
-
United States
-
Anadarko Basin (7)
-
Arkansas
-
Benton County Arkansas (2)
-
Boone County Arkansas (2)
-
-
Arkoma Basin (2)
-
Bighorn Basin (1)
-
Cherokee Basin (5)
-
Colorado
-
San Juan volcanic field (1)
-
-
Illinois (1)
-
Indiana (1)
-
Iowa (1)
-
Kansas
-
Cherokee County Kansas (1)
-
Comanche County Kansas (1)
-
Harper County Kansas (1)
-
Osage County Kansas (1)
-
Reno County Kansas (2)
-
Sedgwick Basin (1)
-
-
Michigan
-
Michigan Lower Peninsula
-
Branch County Michigan (1)
-
Ionia County Michigan (1)
-
Macomb County Michigan (2)
-
Otsego County Michigan (2)
-
Wayne County Michigan (1)
-
-
-
Midcontinent (11)
-
Mississippi Valley (1)
-
Missouri
-
Jasper County Missouri (1)
-
McDonald County Missouri (2)
-
Stone County Missouri (3)
-
-
Ohio (1)
-
Oklahoma
-
Alfalfa County Oklahoma (1)
-
Blaine County Oklahoma (1)
-
Delaware County Oklahoma (2)
-
Garfield County Oklahoma (1)
-
Kay County Oklahoma (2)
-
Logan County Oklahoma (4)
-
Mayes County Oklahoma (3)
-
Noble County Oklahoma (1)
-
Oklahoma County Oklahoma (1)
-
Osage County Oklahoma (6)
-
Pawnee County Oklahoma (1)
-
Payne County Oklahoma (4)
-
Wagoner County Oklahoma (1)
-
Woods County Oklahoma (2)
-
-
Ozark Mountains (8)
-
Paradox Basin (1)
-
U. S. Rocky Mountains
-
San Juan Mountains (1)
-
-
Wabash Valley (1)
-
Wyoming (1)
-
-
waste disposal (1)
-
well-logging (4)
-
X-ray analysis (1)
-
-
rock formations
-
Lucas Formation (1)
-
-
sedimentary rocks
-
sedimentary rocks
-
carbonate rocks
-
dolostone (2)
-
grainstone (3)
-
limestone
-
microbialite (1)
-
-
packstone (3)
-
wackestone (2)
-
-
chemically precipitated rocks
-
chert (6)
-
evaporites (2)
-
-
clastic rocks
-
diatomite (2)
-
mudstone (7)
-
red beds (1)
-
sandstone (7)
-
shale (2)
-
siltstone (2)
-
-
coal (1)
-
-
siliciclastics (7)
-
-
sedimentary structures
-
mounds (1)
-
sedimentary structures
-
bedding plane irregularities (1)
-
biogenic structures
-
stromatolites (1)
-
-
planar bedding structures
-
bedding (1)
-
cross-bedding (1)
-
laminations (1)
-
-
secondary structures
-
concretions (1)
-
-
-
-
sediments
-
sediments
-
carbonate sediments (1)
-
clastic sediments
-
mud (1)
-
-
marine sediments (1)
-
-
siliciclastics (7)
-
Pore system characterization in diagenetically complex Mississippian-aged carbonate reservoirs (Kansas, USA)
Fluid Histories of Middle Ordovician fault–fracture hydrothermal dolomite oil fields in the southern Michigan Basin, U.S.A.
ABSTRACT Multiple orders of depositional cyclicity in the Mayes Group of northeastern Oklahoma are delineated by refined depositional facies associations and stratigraphic surfaces. Facies associations include deep subtidal facies, shallow subtidal facies (including distal and proximal subfacies), carbonate shoal facies, and shoal crest facies. The Mayes Group records a primary transgressive–regressive depositional cycle bounded below by a major unconformity (sub-Mayes unconformity) and above by an important provincial conodont biostratigraphic boundary and widespread flooding surface at the base of the Fayetteville Shale. Within the Mayes Group, two secondary transgressive–regressive depositional cycles are separated by an interpreted unconformity. The lower Mayes cycle comprises the Bayou Manard and Lindsey Bridge members of the Pryor Creek Formation, whereas the Ordnance Plant Member is grouped with the Hindsville Formation in the upper Mayes cycle. Present in both the lower and upper Mayes cycles are high-frequency shallowing-upward cycles bounded by flooding surfaces. Evaluating the distribution of facies and stratigraphic surfaces within a framework of multiple orders of depositional cyclicity is essential to interpreting the geologic evolution of the southern mid-continent during the Meramecian and Chesterian, and impacts oil and gas production by improving our understanding of reservoir compartmentalization.
ABSTRACT Exploration for hydrocarbons in Mississippian strata in Kansas and Oklahoma began in the 1900s. Early production came from open-hole completions in vertical wellbores at the apex of structural and stratigraphic traps. In the mid-20th century, cased-hole completions and hydraulic fracture stimulation allowed development of lower permeability zones. Recently operators began to explore and develop transition zones and low-permeability facies with horizontal drilling. The petroleum system that includes these accumulations consists of two hydrocarbon kitchens in the Arkoma and Anadarko basins, which have been generating oil and gas from the Woodford Shale since the beginning of the Pennsylvanian. Hydrocarbons charged out of the basins and along the fractured terrain of the Cherokee platform into reservoirs from Kinderhookian to Chesterian age across the carbonate facies belt. The distribution of these reservoirs, including limestones, dolomites, and cherts, along with structural configuration, governs the relative abundance and location of oil, gas, and water in each trap. The past decade saw over four thousand laterals targeting Mississippian reservoirs, including shales in unconventional traps, and the greatest rise in oil production in the region since the 1920s. High associated water volumes have created escalating operational costs and are correlative with earthquake activity.
Tournaisian (Mississippian) Carbonate Mounds in the Ozark Region, North America and Ireland: A Comparison
ABSTRACT Mississippian (Tournaisian–Viséan) carbonate mounds in the Compton and Pierson limestones, Ozark region, North America, have been called Waulsortian. However, European Waulsortian mounds contain features such as geopetals with multigenerations of carbonate mud (polymuds) and stromatactis cavity systems that are rare to absent in Ozark mounds. To determine similarities and differences, examine their origins, and clarify nomenclature, mounds in the Compton and Pierson limestones are compared with Waulsortian mounds in the Feltrim Limestone, Ireland. Features considered included mound size, geometry, style of aggradation, composition, depositional setting, and diagenetic history. Mounds in the Compton and Pierson limestones are <10 m (33 ft) thick and form singular knoll-form or aggregates with a strong lateral growth component. In contrast, individual Waulsortian mounds in the Feltrim Limestone range from 5 to > 30 m ( 16 – 100 ft ) thick, but coalesce and vertically aggrade to form complexes that exceed 500 m ( 1600 ft ) . Pierson mounds are crinoidal and grain-rich, whereas Compton and Feltrim mounds are bryozoan-rich and mud-dominated. All mounds have similar cement stratigraphy and diagenetic histories. Mud-rich Compton mounds and Feltrim mounds are interpreted as deeper water than skeletal-rich Pierson mounds. Limited accommodation constrained Compton and Pierson mound size and forced lateral aggradation. Subsidence-driven accommodation in the Dublin Basin allowed Feltrim mounds to grow larger, coalesce, and aggrade vertically. Three types of mounds are recognized: true Waulsortian in the Feltrim Limestone, mud-cored Waulsortian-type Compton and Pierson mounds, and Pierson transported bioaccumulation mounds. Small dimensions of Waulsortian-type Pierson and Compton mounds limit their potential as oil and gas reservoirs, whereas Pierson crinoidal sediment piles are known to form reservoir-size accumulations.
ABSTRACT Production-scale variability in Mississippian reservoirs of the U.S. midcontinent is poorly understood, largely due to distant spacing of subsurface wells and the lack of outcrops that provide a 3-D distribution of potential reservoir facies. This study utilizes exposures of Upper Mississippian (Meramecian to Chesterian in age) lithofacies in a quarry to develop a 1st-order 3-D facies model at a production or enhanced-production scale (<40 ac [<16.2 ha]). By utilizing photogrammetry to stitch and georeference high-resolution aerial photos, 3-D representations of outcropping walls and pavement were created at a submeter resolution and serve as valuable tools for the visualization of bed and facies relationships in 3-D space. Drone-based aerial and orthogonal photography was used to capture images and create 3-D models of inaccessible outcrop areas. These models were then imported as base surfaces to geostatistical reservoir modeling software (Petrel), in which they were integrated with petrographic and sequence-stratigraphic data to model facies and porosity relationships. Various algorithms and variogram lengths were tested and compared to high-resolution outcrop data to determine the most appropriate workflow for future subsurface modeling. The Petrel-based facies and porosity models illustrate the lateral and vertical variability that exists in outcrop while providing detailed approximations of subsurface reservoir heterogeneity.
Controls on Diagenetic Pathways in Mississippian Carbonates of the Anadarko Shelf, Oklahoma
ABSTRACT Few detailed diagenetic studies have been carried out on the Mississippian limestone of north-central Oklahoma, U.S.A. Facies analysis, petrographic observations, and stable isotope data are integrated to investigate diagenetic history. This progradational succession of heterozoan–biosiliceous carbonates accumulated on the southern margin of the Burlington–Anadarko shelf. Diagenetic products related to mesogenesis are pervasive, whereas those related to eogenesis and hydrothermal alteration are localized. A pervasive burial diagenetic overprint is consistent with patterns in stable isotopic data, the bulk of which define a trend of large decreases in δ 18 O ( − 1.5 ‰ to − 7.5 ‰ ) accompanied by relatively small decreases in δ 13 C ( + 3.5 ‰ to + 1.5 ‰ ) values. Microbioclastic skeletal wackestone–packstones are prominent. Due to low diagenetic potential, these facies entered the burial realm essentially unlithified. They are characterized by features that point to chemical compaction as the primary driver for lithification. Spicule-rich facies experienced a different diagenetic pathway, with silicification leading to lithification prior to physical compaction. Late-stage fracturing and hydrothermal alteration, significant elsewhere in the basin, is only locally developed. Porosity is associated largely with late-stage fractures and solution seams resulting from chemical compaction.
ABSTRACT Natural fractures are common in several unconventional reservoirs in the U.S. and around the world and, even when sealed with cements, can facilitate the propagation of induced fractures during hydraulic fracturing. This study is focused on correlating fracture types and intensity to distinct petrophysically significant facies and to an established sequence stratigraphic framework in the unconventional carbonate reservoirs of the “Mississippian limestone” of the U.S. midcontinent region. Four fracture types are observed: ptygmatic, vertical extension, shear, and mixed types of fractures. Most of the fractures have been completely sealed with predominantly calcite cement. Fractured zones are vertically heterogeneous at various scales, indicating the variability in rock mechanical properties. At the millimeter scale, fractures are commonly discontinuous and exhibit variable kinematic aperture. At the centimeter scale, ptygmatic fractures exhibit variable termination modes in relation to bedding planes, suggesting a mineralogical control on rock mechanical properties. At the meter scale, the highest fracture abundance corresponds to facies with the highest calcite content. The mineralogical control of fracture distribution is also represented by the higher fracture intensity within the regressive phases of “third-order” sequences, indicating the value of sequence stratigraphic approach in characterizing and predicting fracture distribution in these unconventional reservoirs.
ABSTRACT Four conodont biozones, including three subzones, are interpreted within a revised lithostratigraphic framework for the upper Boone Group and Mayes Group in northeastern Oklahoma and adjacent parts of Missouri, Kansas, and Arkansas. Although revised lithostratigraphy is principally based on observed lithologic characteristics and stratigraphic relationships, conodont biostratigraphic data played an important role in correlation and final organization of units. Within the upper Boone Group, Biozone 1 (lower Meramecian) includes the Ritchey Formation and the Tahlequah limestone and Biozone 2 (middle Meramecian) includes the Moccasin Bend Formation and Quapaw Limestone. The Mayes Group spans Biozone 3 and Biozone 4. Biozone 3 (upper Meramecian) is represented by the Bayou Manard Member of the Pryor Creek Formation (new name). Biozone 4 marks the appearance of definitive Chesterian conodont fauna. The lower two subzones within Biozone 4 correspond to the Lindsey Bridge (Biozone 4L) and Ordnance Plant (Biozone 4M) members of the Pryor Creek Formation, whereas the upper subzone consists of the Hindsville Formation (Biozone 4U). Documentation of conodont taxa and recognition of the proposed biozones provides relative time constraints for genetically meaningful interpretations of regional geology and subsequent evaluation of the Mayes Group and upper Boone Group within a broader interregional context.
ABSTRACT Lithologies, depositional environments, stratigraphic architecture, and conodont biostratigraphy of Lower to Middle Mississippian rocks in the western Ozarks comprise five depositional sequences in ramps on the southern Burlington shelf. Aggradational ramps in the Kinderhookian to early Osagean St. Joe group were relatively strongly overprinted by Ouachita-related tectonism involving inferred recurrent passage of fore-bulge highs and associated basins across central and southern parts of the outcrop area. Significant effects of tectonism are southward facies shallowing onto the broad Kanoka ridge paleotopographic high associated with locally extensive marine and lesser subaerial erosion, sediment thickening and deposition of generally northward down-lapping, resedimented wedges with dislodged reef blocks and conglomerates into relatively rapidly subsiding basins, and formation of a regionally extensive paleosol at the top of the group. Back-stepping subsidence due to middle Osagean foundering of the Kanoka ridge was followed by rapid, long-distance progradation of middle- and outer-ramp facies in the Bentonville and Reeds Spring limestones. Tectonism at this time resulted variously in local folding, uplift, marine and subaerial erosion, and reversal of shelf bathymetry. Southward erosion of the Reeds Spring and Bentonville occurred at least in Oklahoma on rejuvenated segments of the Kanoka ridge. Overlying lower Meramecian limestones are shallow-water deposits truncated by a major unconformity.
ABSTRACT Petrographic, geochemical, and fluid inclusion analysis of dolomite and calcite cements has been conducted on Mississippian carbonates collected from the surface and subsurface of the southern midcontinent of the United States (Oklahoma, Missouri, Kansas, and Arkansas). Fracture and vug, intergrain, and intragrain porosity are filled with calcite, authigenic quartz, and dolomite cements. Primary limestone porosity is filled partially by early marine and meteoric calcite cements. Equant (blocky) calcite cements were precipitated under seawater or mixed meteoric-seawater conditions in the phreatic zone and in the deep phreatic zone under late (burial) diagenetic conditions. Fracture- and breccia-filling saddle dolomite cements that were observed are late diagenetic and are likely related to the nearby Tri-State Mississippi Valley-type (MVT) mineral district. Carbon and oxygen isotope values of dolomite cements range from δ 18 O (VPDB) = −9.5 to −2.7‰ and from δ 13 C (VPDB) = −4.0 to −0.4‰. Values for calcite cements range from δ 18 O (VPDB) = −11.6 to −1.9‰ and from δ 13 C (VPDB) = −12.2 to +4.6‰. These values are consistent with three types of diagenetic fluids: seawater, seawater modified by meteoric water, and evolved basinal water. Analysis of fluid inclusions in late calcite, dolomite, and quartz cements indicates the presence of both dilute and high salinity end-member fluids. Homogenization temperatures (T h ) of fluid inclusions range from 57°C to 175°C and salinities range from 0 to 25 equivalent weight % NaCl. Fluid inclusion T h values and salinities are consistent with a saline basinal fluid variably diluted by fluids of meteoric or mixed seawater and meteoric origin. Petroleum inclusions were observed in late diagenetic calcite and dolomite cements.The late diagenetic cements filled porosity retained after early diagenetic cementation indicating that some original porosity in the Mississippian carbonate rocks remained open during petroleum migration. Elevated fluid inclusion T h values over a broad region, not just in the Tri-State Mineral District, imply that the regional thermal maturity of rocks may be higher than believed previously. This study indicates that the Mississippian carbonate resource play on the southern midcontinent has a very complex diagenetic history, continuing long after early diagenetic cementation. Possibly the most important diagenetic events affecting these rocks occurred during burial and basinal fluid migration through these strata.
ABSTRACT Mississippian depositional systems in the subsurface of Oklahoma consist of a mix of carbonates and siliciclastic rocks that were variously interpreted as deposited on a regional shelf, ramp, or distally steepened ramp. These varied interpretations resulted in significantly different models for associated facies types and distribution, including potential reservoir types and the distribution of these units that may occur in the subsurface. Fundamental differences in the facies types and distribution of a shelf and shelf margin system versus a ramp or distally steepened ramp include the varying regional distribution for high- and low-energy facies, reef facies, and downslope mass transport deposits. Recent work in both the subsurface of Oklahoma, as well as local outcrops in Arkansas and Missouri, indicates that the facies were deposited on a distally steepened ramp due to the lateral facies distribution and the vertical facies successions identified throughout the system. The presence and characteristics associated with debris flows as described in this study, especially when defined within the context of a sequence stratigraphic hierarchy, supports the interpretation of a distally steepened ramp conceptual model and provides insight into similar mass transport deposits that may occur in the subsurface.
Integrated Paleomagnetic and Diagenetic Study of the Mississippian Limestone, North–Central Oklahoma
ABSTRACT The Mississippian limestone is a petroleum exploration target in northern Oklahoma, and diagenetic events are significant factors in controlling porosity. In this study, paleomagnetic data, supported by petrographic results, were used to determine the origin and timing of diagenetic events in five unoriented cores from northern Oklahoma. Petrographic analysis indicates a complex paragenetic sequence, which includes precipitation of sphalerite and baroque dolomite. Thermal demagnetization removes a low-temperature viscous remanent magnetization (VRM) and a chemical remanent magnetization (CRM) in magnetite. An attempt was made to orient the cores using the VRM but this resulted in a streaked distribution of declinations. The inclinations of the CRM in the specimens in the five cores are similar (mean = −2.6°) and the age of the CRM was determined by comparing the inclinations with the expected inclinations for the study area. This indicates remanence acquisition in the Permian (~310–290 Ma). This is consistent with dates for mineralization in the nearby Tri-State MVT deposit and for a hypothesized Permian hydrothermal alteration event in the study area. The age of the CRM and the presence of sphalerite and baroque dolomite suggest that the CRM was acquired via hydrothermal fluids in the Permian.
High-Resolution Stable-Isotope Chemostratigraphy in the Mississippian Limestone of North-Central Oklahoma
ABSTRACT The Mississippian limestone of the midcontinent United States is a complex and highly heterogeneous hydrocarbon play. Its heterogeneity is largely due to the mixed siliciclastic and carbonate nature of the midcontinent Mississippian system, which yields complex reservoir lithologies and distributions that are laterally discontinuous and difficult to predict. The purpose of this study is to apply stable-isotope chemostratigraphy, a relatively recent method for addressing industry-related correlation problems, as an additional reservoir characterization tool that provides insight into chemical attributes of Mississippian-aged sedimentation and how these chemical signatures can be used for potential chronostratigraphic applications. High-resolution sampling (every 0.3 m [1 ft]) of one subsurface core for carbon and oxygen stable isotopes has revealed predictable patterns related to facies and vertical stacking patterns as well as to globally recognized secular changes in ocean chemistry. The chemostratigraphic approach applied herein suggests more frequent third-order cyclicity than recently defined in other subsurface data sets within the basin, which is more consistent with global ties to the individual North American stages and within the Mississippian overall. In addition, δ 18 O values suggest a level of predictability at the fourth-order scale related to shallowing-upward packages and mixed meteoric input at cycle tops. Overall, stable isotope curves closely match those of well-established Mississippian global carbon cycling and have been used to suggest time boundaries in this area of the depositional system.
Isotope Chemostratigraphy of the Lower Mississippian St. Joe Group in Northeastern Oklahoma and Southwestern Missouri
ABSTRACT The St. Joe group (Lower Mississippian, Tournaisian) is petrographically and isotopically analyzed using δ 13 C and δ 18 O bulk sample stable isotopes in central, northeastern Oklahoma, and southwestern Missouri. Determined to be conformable in Oklahoma, this group represents deposition in the mid- to outer-ramp setting during one long-term depositional cycle and can be used as a reference section for geochemical chronostratigraphy. Minor diagenetic alteration did not overprint the initial isotope signal, and the resulting curve is similar to those from previous studies and is integrated with published conodont biostratigraphy. The resulting correlation indicates that the St. Joe group was deposited in the upper Tournaisian Stage.
ABSTRACT Organic-rich Mississippian carbonates and oil samples from wells completed in the Mississippian and Woodford zones in northern Oklahoma were sampled and geochemically assessed to evaluate charge history. Rock and oil samples were collected from the Cherokee platform and the Anadarko shelf. Samples were analyzed using gas chromatography and gas chromatography-mass spectrometry (GC-MS) techniques for quantitative analysis of diamondoids and saturate and aromatic biomarkers. Results indicate Mississippian hydrocarbon source rocks have generation potential and reached the early oil window thermal maturity. Extracted bitumen from Mississippian rocks and related oils show unique biomarker signatures such as the presence of extended tricyclic terpanes and high input of C 27 relative to C 28 and C 29 in regular and rearranged steranes. The extent of cracking, as measured by diamondoids, reveals a dramatic change in diamondoids concentration between areas east and west, respectively, of the Nemaha uplift. The higher concentration of diamondoids and biomarkers observed west of the Nemaha uplift indicates mixing of uncracked oil with cracked oil migrating out of the Anadarko Basin. This mix of uncracked and cracked oils west of the uplift suggests episodic hydrocarbon charge and a long-distance component to the migration model. In contrast, the Mississippian samples from east of the Nemaha uplift are depleted in diamondoids, suggesting limited migration distance and localized hydrocarbon generation under lower thermal stress.
ABSTRACT The Mississippian system in the midcontinent of the United States is a complex carbonate- and chert-dominated system with a large degree of reservoir variability and heterogeneity. An outcrop study was done in the state of Arkansas on the Middle Mississippian (Visean) Burlington-Keokuk Formation to analyze the depositional setting and high-resolution sequence stratigraphic architecture to better understand the reservoir distribution of similar units in the subsurface. The outcrop location, in the northwestern portion of the state of Arkansas, was studied using an integrated sequence stratigraphic approach, combining high-resolution photography for tracing bed boundaries and lithologic contacts along with facies determination from outcrop and thin section analysis. A range of skeletal packstones to grainstones dominated by crinoidal fragments and an abundance of void-filling syntaxial calcite cements comprised the majority of the outcrop facies. Nodular to bedded siliceous limestone to carbonate-rich chert facies were observed containing up to approximately 50% microporosity. Based upon facies assemblages and the presence of meter-scale sand waves with faint cross bedding on outcrop, these units were likely deposited in a high-energy sand shoal or sand bar in a proximal position on a distally steepened ramp. Within the outcrop, multiple shoaling upward packages were observed, consisting of siliceous limestones and cherts at the bases overlain by coarsening and thickening upward grainstone bodies. This stacking pattern was observed at two different scales. Larger-scale packages 15 to 35 feet (5–10 m) thick were mappable and continuous across the entire outcrop (1320 ft [400 m]), and are inferred to be controlled by eustatic sea-level change. A smaller-scale stacking pattern was observed on the meter (several feet) scale and were mappable for 165–500 ft (50–150 m) laterally. The lack of limited lateral correlation is inferred to be due to autocyclic controls within the active sand body. The observed shoaling upward patterns create a hierarchy of stacked reservoir and seal units with superimposed variability. These findings illustrate the potential for high-frequency sea-level change and autocyclic control on facies and reservoir distribution that may be seen in the subsurface. Two-dimensional geostatistical modeling further illustrates the need for this level of characterization, as variogram inputs are biased significantly by the segregation of high-frequency sequences and dominant eustatic or autocyclic controls on deposition.
ABSTRACT Facies analysis utilizing a conodont biostratigraphic framework is a powerful tool for evaluating genetic relationships of Osagean–basal Meramecian strata within the Ozark region (Arkansas–Missouri–Oklahoma) of the southern midcontinent. This investigation builds upon previous work cited herein, and suggests that some lithostratigraphic divisions, although useful in differentiating strata in a localized setting, may not be suitable for regional correlations within the Boone Group. High-resolution conodont biostratigraphy demonstrates the diachronous nature of lithostratigraphic divisions within the Boone Group, with both the Reeds Spring Formation and Bentonville Formation (Burlington–Keokuk) clearly becoming younger as they are traced from southwestern Missouri into northern Arkansas and northeastern Oklahoma. Subsequent facies analysis shows that the Reeds Spring Formation represents deposition within outer ramp through proximal middle ramp settings (low to moderate energy), whereas the Bentonville Formation (Burlington–Keokuk) records deposition within proximal middle ramp to inner ramp settings (moderate to high energy). Integration of facies analysis and conodont biostratigraphy-based relative chronostratigraphy provides the basis for construction of four time-slice maps illustrating the distribution of time-correlative facies belts. Together, these time-slice maps deliver a clearer representation of the evolution of Boone Group carbonate ramp deposition during the Osagean, which was characterized by overall shallowing-upward and progradation to south and southwest.
ABSTRACT Mississippian rocks in north-central Oklahoma were deposited on a ramp-shelf system that trended along an approximate northeast–southwest strike and that deepened to the southeast and southwest into the Arkoma and Anadarko basins. The system is bounded on the east by the Ozark uplift. Structure in this area is dominated by extensional and transverse faulting associated with the Transcontinental arch (Nemaha uplift). Shallower water (shelf) depositional settings dominate in the northern part of the study area and deepen toward the south into the Anadarko and Arkoma basins. Sedimentary rocks on the carbonate ramp are dominated by cyclic, partially dolomitized, argillaceous mudstones interbedded with fine-grained wackestones to grainstones. Intergrain pore space is filled by bladed, isopachous, and syntaxial marine calcite cements followed by blocky calcite cements. Limestone is commonly replaced by chert with intergrain open space filled by fine crystalline quartz (chert) cement. Late diagenetic fracture, breccia, and vug (FBV) porosity are filled by calcite and less commonly, by quartz cement that displays a coarse, blocky habit. Carbon and oxygen isotope values for limestones and replacive dolomite are consistent with precipitation from Mississippian seawater and mixed seawater–meteoric water; values for FBV-filling calcite cements indicate precipitation from evolved basinal waters. The 87 Sr/ 86 Sr values of calcite micrite, replacement dolomite, and fracture-filling calcite range from 0.7077 to 0.7112. The lower values are consistent with equilibration with Mississippian seawater through most of the study area. More radiogenic 87 Sr/ 86 Sr values for fracture-filling calcite cements in the northeast part of the study area indicate interaction with continental basement rocks or siliciclastic rocks derived from continental basement. Two-phase (liquid plus vapor) aqueous and petroleum inclusions were observed in FBV-filling calcite and quartz cements. The aqueous inclusions have homogenization temperatures of 48°C to 156°C and salinities ranging from 0 to 25 equivalent weight % NaCl equivalent, and reflect the presence of distinct dilute and saline fluid end-members. Calculated equilibrium δ 18 O water values (VSMOW) for fluids that precipitated fracture-filling calcite cements are variable, ranging from –0.3 to +14.5‰ and do not reflect a single end-member water. Early diagenesis was dominated by seawater-involved cementation, with modification by meteoric water during sea-level low-stands. FBV-filling calcite and quartz represent a later stage of diagenesis associated with petroleum generation and migration. Formation of fractures in the Mississippian section in north-central Oklahoma likely is related to fault movement along the Nemaha ridge instigated by Ouachita tectonism during the Pennsylvanian and extending into the Permian. This timing corresponds with regional flow of saline basinal fluids associated with the orogenic activity. These fluids ascended along faults and contributed to precipitation of FBV-filling cements. Calculated δ 18 O water values for calcite cement in some areas of north-central Oklahoma suggest that cement-depositing fluids approached isotopic equilibrium with the host carbonate rocks. In other areas, however, cement-depositing fluids have oxygen isotope signatures that reflect nonresident fluids whose flow was restricted to fault and fracture pathways, which did not permit isotopic equilibration with the host limestone. In particular, fracture-filling calcite veins from Osage County, with high 87 Sr/ 86 Sr (>0.710) and low δ 13 C values (–2.3‰ to –4.1‰), reflect fluids that retained isotopic characteristics that were derived through interaction with subjacent shale source rocks.
ABSTRACT Mississippian carbonates of northern Oklahoma were deposited on the Anadarko shelf (ramp) as several shallowing-upward sequences. In Woods County, Oklahoma, the Mississippian ranges in thickness from 350 ft (105 m) to the south to as little as 100 ft (30 m) to the north due to uplift and erosion. Lithologies observed in core are chert conglomerate, tripolitic chert (tripolite), dense chert, chert-rich limestone, dense limestone, and shale-rich limestone. To evaluate the spatial distribution of Mississippian lithologies and petrophysical properties, and to explore the controls on production, this study integrates 3-D seismic with core and well-log data. As a constraint for 3-D lithology modeling, lithology logs were estimated using a neural-network approach with core and log data resulting in 65.1% accuracy. A P-impedance volume from seismic inversion was used to constrain the spatial distribution of tripolite in the model, the main reservoir lithology. Lithology-constrained 3-D porosity and water saturation models show that tripolite is the most porous and heterogeneous lithology. Comparing lithology, porosity, and water saturation models to production data illustrates that production from vertical wells is primarily controlled by porous tripolite distribution, whereas horizontal wells produce from both tripolite and chert-rich limestones and are most sensitive to water saturation variations.