Persian Gulf Basin
Persian Gulf Basin | |
---|---|
Stratigraphic range: Precambrian to Neogene | |
Type | Foreland Basin |
Area | 240,000 km2 (93,000 sq mi) |
Thickness | 12 to 13 km [1] |
Location | |
Location | Iran, Iraq, Kuwait, Saudi Arabia, Qatar, Bahrain, United Arab Emirates and Oman (exclave of Musandam) |
Region | Western Asia |
Type section | |
Country | Iran, Kuwait, United Arab Emirates, Saudi Arabia, Qatar, Oman, Bahrain and Iraq |
The Persian Gulf Basin (
Persian Gulf Basin and the Middle East
A collection of these countries is commonly referred to as the Middle East which is the oil-rich location in the south western side of the Asia continent. A review of the world's energy with different estimates indicates that the Middle East holds 55% to 68% of the world's oil deposits and more than 40% of the world's recoverable natural gas reserves.
Worldwide, it is the richest side of the world in terms of hydrocarbon resources, both oil and gas reserves with an area of approximately 93000 square miles. The name Persian Gulf in most cases refers not only to the Persian Gulf but also the Gulf of Bahrain, the Gulf of Oman, and the Strait of Hormuz as well as various outlets that are linked to the Arabian Sea.
Tectonic evolution
The Arabian Plate tectonic origin is grouped into six phases which contributed to its current geology:
Precambrian phase
The early Precambrian (from 800 to 650 Ma) is a compressional phase where a series of islands-arcs and micro-continent terrane accreted to form the oldest portions of the Arabian Plate (Gondwana). The development of Hormuz saltbasin was a consequence of the last Precambrian orogenic event.[2]
Ordovician-Silurian glaciations
An expanding of polar glaciation in Gondwana occurred in the Late
Carboniferous phase
During the Late Devonian, the plate was located in a back-arc-setting. The initiation of the Hercynian Orogeny led to the uplift of the central Arabian plate and tilted it eastward, which resulted in a basement tectonism and extensive erosion. The Arabian Plate underwent many compressional phases during this period.[3]
Early Triassic
Thermal subsidence and Arabian plate stretching (that resulted from the fragmentation of Gondwana in the Late Permian) resulted in extensional faulting and the early rifting of Zagros that opened the Neo-Tethys Sea.[3]
Late Cretaceous phase (early Alpine orogeny)
This period was where the Alpine Orogeny started to form as a result of compression, which resulted in major uplifts and erosions, in addition to the closure of Neo-Tethys Sea.
Tertiary phase (late Alpine orogeny)
During this period there was the second
History of natural resources
The extensive
Most of the oil in the Persian Gulf basin is produced from the Jurassic carbonates. However, presently, the rocks rich in organic hydrocarbons exist in three major geological systems:[3]
- Paleozoic petroleum system
- Jurassic petroleum system
- Cretaceous petroleum system
Oil and gas are formed in a source rock (mostly shales), and then they migrate to the reservoir layer of rocks (carbonates). After that, the formation of structural folds and faults in the reservoir rocks leads to the natural creation of zones where the natural resources become trapped and stored as reserves that are commercially recoverable.[3]
Four major tectonic events resulted in the formation of structural
- Carboniferous Hercynian Orogeny
- Early Triassic Zagros rifting
- First (or early Oman) Alpine Orogeny
- Second (or late) Alpine Orogeny
which led to the collection and successive generations of the hydrocarbons after undergoing deformation and other processes that resulted in the final compartmentalization. In the middle Persian Gulf, large volumes of natural gas collections in Permo-Triassic accumulations have a direct link to the hot shale rocks found in the lower base-Silurian formation. Then the oil migrated to the carbonates reservoir rocks and finally was trapped in the four major traps, which explains why the Persian Gulf basin is one of the richest basins in terms of hydrocarbon resources.[citation needed]
Structural and tectonic settings
The Arabian Plate shows divergent margins around the adjacent areas of the Gulf of Aden, Red Sea and the south western side of the Arabian plate. On the south and south eastern side of the Arabian plate lies the Owen-Sheba which is an intra-oceanic transform fault. Then there is convergent margin located on the north and north eastern side close to Turkey and in the Zagros Mountains located on the east of Iran, where the Arabian plate is subducting underneath the Eurasian plate. Lastly the Dead Sea, which is a transform fault zone found on the north western side of the Arabian plate.[2]
The current deformation and accumulation processes that are related to the natural structures and the subsequent compression of the layers within the Persian Gulf illustrates the origin of the various natural resources found in the place, the geologic processes and the tectonic regimes that occurred.[5]
The tectonic representation of the Middle East is divided into three parts that have different characteristics concerning their age, thickness and types of rocks :[6]
- Stable Arabian shelf
- Unstable Arabian shelf
- Zagros fold-and-thrust belt
The end of the Paleozoic experienced some transformations in terms of subsidence differentiations and sea level rise that led to the formation of structural elements such as the three troughs:
- Arabian Trough – in the middle part of the basin which is largely covered by Saudi Arabia and Bahrain.[1]
- Gotnia Trough – in the northern side of the basin covering Iraq and Syria.[1]
- Rub-Al-Khali – in Saudi Arabia and United Arab Emirates.[1]
Most of the geological characteristics were established during the Paleozoic which were initiated by the continuous continental marine sedimentation on the north east side of Gondwana.[1] Some complex events which were effects of the Carboniferous processes also affected the area through creation of regional uplift, extensive erosions some basement tectonics. Therefore, the consistent tectonic geological evolution and the structural settings that resulted thereafter formed the Arabian plate after successive tectonic regimes.[6]
References
- ^ a b c d e f A. I. Konyuhov, B. Maleki, The Persian Gulf Basin: Geological history, sedimentary formations, and petroleum potential / Lithology and Mineral Resources. July 2006, Volume 41, Issue 4, pp 344–361 doi:10.1134/S0024490206040055
- ^ a b c d . A Brief Tectonic History of the Arabian basin. Retrieved from the website: http://www.sepmstrata.org/page.aspx?pageid=133
- ^ a b c d e f . Total Petroleum Systems of the Paleozoic and Jurassic, Greater Ghawar Uplift and Adjoining Provinces of Central Saudi Arabia and Northern Arabian-Persian Gulf. Retrieved from the website: http://pubs.usgs.gov/bul/b2202-h/b2202-h.pdf
- ^ : Cairo to Doha. Persian Gulf at 13,000 m- A flooded basin. Retrieved from the website: "Details of Persian Gulf at 13,000m - A flooded basin - Cairo to Doha - Persian Gulf at 13,000m - A flooded basin". Archived from the original on 2016-03-04. Retrieved 2015-02-21.
- ^ Digital Commons: University of Nebraska, Lincolin. (2011). Late Cretaceous to Recent Deformation Related to Inherited Structures and Subsequent Compression within the Persian Gulf: 2D Seismic Case Study. Retrieved from the website: http://digitalcommons.unl.edu/cgi/viewcontent.cgi?article=1294&context=geosciencefacpub
- ^ a b "Why So Much Oil in the Middle East?" GEOEXPRO2010: 20-28. Web. 10 Feb. 2015.<http://assets.geoexpro.com/uploads/696e7ae7-cb6c-46bd-b10b-2a3277b67447/GEO_ExPro_v7i1_Full.pdf