User:Eleanor W Smith/The Permian Basin sandbox

The West Texas Permian Basin

The Permian Basin is a 400 km long, 480 km wide sedimentary basin located in western Texas and southeastern New Mexico within the foreland of the Ouachita-Marathon thrust belt and consisting of the thickest succession of Permian age rocks on Earth. The Basin began as a passive continental shelf known as the Tobosa Basin that was deformed into its current two lobed geometry during the Hercynian Orogeny in the late Mississippian-Pennsylvnian periods. The modern basin is composed of the Delaware and Midland Basins separated by the uplifted Central Basin Platform. The Permian is well known as one of the most lucrative hydrocarbon reservoirs in the world, providing more than half the world's Permian aged hydrocarbons. ^{[1] [2] [3]}

Components of the Permian Basin

The Delaware Basin

Figure 2

File:Capitan Reef Complex.png

Figure 3: Capitan Reef Complex

The Delaware Basin is largest lobe of the two major lobes of the Permian Basin within the foreland of the Ouchita-Marathon thrust belt separated by the Central Basin Platform The basin contains sediment from the Pennsylvanian, Wolfcampian, Leonardian, and early Guadalupian times. The eastward dipping Delaware basin is subdivided into the formations listed in figure 2 and contains approximately 25,000 feet of laminated siltstone and sandstone. Aside from clastic sediment, the Delaware basin also contains carbonate deposits originating from the Guadalupian times when the Hovey Channel allowed access from the sea into the basin. ^[2]

The Midland Basin

Figure 4

File:Midland Basin.gif

Figure 5: Midland Basin Stratigraphy

The westward dipping Midland Basin is subdivided into the formations listed in figure 3 and is composed of laminated siltstone and sandstone. The Midland Basin was filled via a large subaqeuous delta that deposited clastic sediment into the basin. Aside from clastic sediment, the Delaware basin also contains carbonate deposits originating from the Guadalupian times when the Hovey Channel allowed access from the sea into the basin.^[2]

Central Basin Platform

Figure 5

The Central Basin Platform is a tectonically uplifted basement block capped by a carbonate platform. The CBP separates the Delaware and Midland Basins and is subdivided into the formations listed in figure 5 and is composed of carbonate reef deposits and shallow marine clastic deposits.^[2]

Eastern and Northwest Shelves

The Eastern and Northwestern Shelves are composed of shelf edge reefs and shelf carbonates flanking the Delaware and Midland Basins that grade up-dip into siltstones and evaporites. The Eastern and Northwestern Shelves are subdivided into the San Andreas, Grayburg, Queen Seven Rivers, Yates, and Tansil formations.^[2]

San Simon Channel

The San Simon Channel is a narrow syncline that separated the Central Basin Platform from the Northwestern Shelf during Leonardian and Guadalupian times.^[2]

Sheffield Channel

The Sheffield Channel separated the southern margin of the Midland Basin from the southern shelf and the Ouchita-Marathon thrust-belt during Leonardian and Guadalupian times.^[2]

Hovey Channel

The Hovey Channel is a topographical low located on the southern edge of the Delaware Basin, allowing access to the Panthalassa sea during Guadalupian times.^[2]

Depositional History

The Permian Basin is thickest deposit of Permian rocks on Earth and were rapidly deposited during the collision of North America and Gondwana Land (South America and Africa) between the late Mississippian through the Permian.

Lower Paleozoic (Upper Cambrian to Mississippian)

Prior to the breakup of the Precambrian supercontinent and the formation of the modern Permian Basin geometry, shallow marine sedimentation onto to the ancestral Tobosa Basin characterized the passive margin, shallow marine environment.

Upper Mississippian-Lower Permian

The collision of North America and Gondwana Land (South America and Africa) during the Hercynian Orogeny created the Ouachita-Marathon thrust belt and the associated foreland basins, the Delaware and Midland Basins, separated by the Central Basin Platform. The tectonic activity resulted in the distribution of voluminous siliciclastic sediments into the basins during the Early Pennsylvanian. Siliciclastic sedimentation was followed by the formation of carbonate shelves and margins at the basin flanks in the Early Permian.

Upper Permian

After the Hercynian Orogeny, 4 km of sediment filled the rapidly subsiding Delaware and Midland basins. The Midland basin was filled by about 270 mya, as it received the majority of clastic sediment from the Hercynian Orogeny via a subaqueous delta, while the Delaware Basin continued to fill until the late Permian. Sandstones and some deep water, organic rich shales were deposited within the basins while reef carbonates were deposited on the Central Basin Platform and on the shelves of the basins. The extensive reef deposits fringing the Delaware Basin became known as the Capitan limestone. In the later Guadalupian, the Permian sea retreated, and the basins were capped with easy evaporite deposits, including salts and gypsum. The deep water shales and carbonate reefs of the Delaware and Midland Basins and the Central Basin Platform would be become lucrative hydrocarbon reservoirs. ^{[2] [4]}

Generalized Facies Tracts of the Permian Basin

The Permian basin is divided into generalized facies belts differentiated by the depositional environment in which they formed, influenced by sea level, climate, salinity, access to the sea.

Lowstand Systems Tract

Lowering sea level exposes the peritidal and potentially, the shelf margin regions, allowing linear channel sandstones to cut into the shelf, extending beyond the shelf margin atop the slope carbonates, fanning outward toward the basin. The tidal flats during a lowstand contain aeolian sandstones and siltstones atop supratidal lithofacies of the transgressive systems tract. The basin fill during a lowstand is composed of thin carbonate beds intermingled with sandstone and siltstone at the shelf and sandstone beds within the basin.

Transgressive Systems Tract

This facies results from the abrupt deepening of the basin and the reestablishment of carbonate production. Carbonates such as bioturbated wackstone and oxygen poor lime mud accumulate atop the underlying lowstand systems tract sandstones in the basin and on the slope. The tidal flats are characterized by supratidal faces of hot and arid climate such as dolomudstones and dolopackstones. The basin is characterized by thick carbonate beds on or close to the shelf with the shelf margin becoming progressively steeper and the basin sandstones becoming thinner.

Highstand Systems Tract

Hightand systems tract facies results from the slowing down in the rise of sea level. It is characterized by carbonate production on the shelf margin and dominant carbonate deposition throughout the basin. The Lithofacies is of thick beds of carbonates on the shelf and shelf margin and thin sandstone beds on the slope. The basin becomes restricted by the formation of red beds on the shelf, creating evaporites in the basin.^{[5] [4] [6]}

Tectonic History

During the Cambrian-Mississippian, the ancestral Permian Basin was the broad marine passive margin Tobosa Basin containing deposits of carbonates and classics. In the early Pennsylvanian-early Permian the collision of North American and Gondwana Land (South America and Africa) caused the Hercynian Orogeny. The Hercynian Orogeny resulted in the Tobosa basin being differentiated into two deep basins (the Delaware and the Midland Basins) surrounded by shallow shelves. During the Permian, the basin became structurally stable and filled with clastics in the basin and carbonates on the shelves. ^[7]

Lower Paleozoic Passive Margin Phase (late Precambrian-Mississippian, 850-310 Ma)

This passive margin succession is present throughout the southwestern US and is up to 1.5 km thick. The ancestral Permian basin is characterized by weak crustal extension and low subsidence in which the Tobosa basin developed. The Tobosa basin contained shelf carbonates and shales. ^[8]

Collision Phase (late Mississippian-Pennsylvanian, 310-265 Ma)

The two lobed geometry of the Permian basin separated by a platform was the result of the Hercynian collisional orogeny during the collision of North America and Gondwana Land (South America and Africa). This collision uplifted the Ouachita-Marathon fold belt and deformed the Tobosa Basin. The Delaware Basin resulted from tilting along areas of Proterozoic weakness in Tobosa basin. Southwestern compression reactivated steeply dipping thrust faults and uplifted the Central Basin ridge. Folding of the basement terrane split the basin into the Delaware basin to the west and the Midland Basin to the east. ^{[7] [9]}

Permian Basin Phase (Permian, 265-230 Ma)

Rapid sedimentation of clastics, carbonate platforms and shelves, and evaporites proceeded synorogenically. Bursts of orogenic activity are divided by three angular unconformities in basin strata. Evaporite deposits in the small remnant basin mark the final stage of sedimentation as the basin became restricted from the sea during sea level fall. ^{[8] [10]}

Hydrocarbon Plays

File:Active wells on the Permian Basin.jpg

Figure 6: Active oil (green) and gas (red) wells on the Permian Basin, Texas

Figure 7: Significant hydrocarbon plays within the Permian Basin

The Permian Basin is the largest petroleum-producing basin in the United States and has produced a cumulative 28.9 billion barrels of oil and 75 trillion cu ft. of gas. Currently, nearly 2 million barrels of oil a day are being pumped from the basin, which still contains an estimated 43 billion barrels of oil and 18 trillion cu ft. of gas. 80% of estimated reserves are located at less than 10,000 ft. depth. Ten percent of the oil recovered from the Permian basin has come from Pennsylvanian carbonates. The largest reservoirs are within the Central Basin Platform, the Northwestern and Eastern shelves, and within Delaware Basin sandstones. The Primary lithologies of the major hydrocarbon reservoirs are limestone, dolomite, and sandstone due to their high porosities. However, advances in hydrocarbon recovery such as horizontal drilling and hydraulic fracturing have expanded production into unconventional, tight oil shales such as those found in the Wolfcamp formation. ^{[11] [3]}

References

1. Galley, John (1995). "Oil and Geology in the Permian Basin of Texas and New Mexico". {{cite journal}}: Cite journal requires |journal= (help)
2. Ward, R.F.; et al. (1986). "Upper Permian (Guadalupian) facies and their association with hydrocarbons-Permian basin, west Texas and New Mexico". AAPG Bulletin. 70: 239–262. {{cite journal}}: Explicit use of et al. in: |last1= (help)
3. Wright, Wayne (2011). "Pennsylvanian paleodepositional evolution of the greater Permian Basin, Texas and New Mexico: Depositional systems and hydrocarbon reservoir analysis". AAPG Bulletin. 95: 1525–1555.
4. Hunt, David; et al. (2002). "Syndepositional deformation of the Permian Capitan reef carbonate platform, Guadalupe Mountains, New Mexico, USA". 154: 89–126. {{cite journal}}: Cite journal requires |journal= (help); Explicit use of et al. in: |last1= (help)
5. Ross, C.A.; et al. (1995). The Permian of Northern Pangea 1: Paleogeography, Paleoclimates, Stratigraphy. Springer-Verlag. pp. 98–123. {{cite book}}: Explicit use of et al. in: |last1= (help)
6. Siver, Burr (1969). "Permian Cyclic Strata, Northern Midland and Delaware Basins, West Texas and Southeastern New Mexico". AAPG Bulletin. 53 (11).
7. Hills, J.M. (1984). "Sedimentation, tectonism, and hydrocarbon generation in the Delaware basin, West Texas and Southeastern New Mexico". AAPG Bulletin. 68: 250–267.
8. Horak, R.L. (May 27, 1985). "Tectonic and hydrocarbon maturation history in the Permian basin". Oil and Gas Journal: 124–129.
9. Sarg, J.; et al. (1999). "The second-order cycle, carbonate-platform growth, and reservoir, source, and trap prediction, Advances in carbonate sequence stratigraphy: Application to reservoirs, outcrops and models: Special Publication". SEPM. 63: 11–34. {{cite journal}}: Explicit use of et al. in: |last1= (help)
10. Hoak, T; et al. (1991). "Overview of the Structural Geology and Tectonics of the Central Basin Platform, Delaware Basin, and Midland Basin, West Texas and New Mexico". Department of Energy Publication. {{cite journal}}: Explicit use of et al. in: |last1= (help)
11. Dutton, S.P.; et al. (2005). "Play analysis and leading edge oil-reservoir development methods in the Permian Basin; increased recovery through advanced technologies". AAPG Bulletin. 89 (5): 553–576. {{cite journal}}: Explicit use of et al. in: |last1= (help)