Silurian Qusaiba shales

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Petroleum Systems Analysis—Case Studies
Series Memoir
Chapter A petroleum system and basin modeling study of northwest and east-central Saudi Arabia: Effect of burial history and adjacent rock lithology on the gas potential of the Silurian Qusaiba Shales
Author Sedat Inan, Mahdi A. AbuAli, Ahmed M. Hakami
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Geological Settings

The geological history of the Arabian Basin, which is a part of the Arabian Plate (Figure 1), has been discussed in detail (e.g., Powers et al., 1966[1]; McGillivray and Al-Husseini, 1992[2]; Alsharhan and Nairn, 1997[3]; Wender et al., 1998[4]; Al-Hajri and Owens, 2000[5]; Al-Husseini, 2000[6]; Konert et al., 2001[7]; Sharland et al., 2001[8]; Ziegler, 2001[9]; Faqira et al., 2009[10]; Cantrell et al., 2014[11] and references cited therein).

Figure 1 Oil and gas fields in the Arabian Plate and distribution of Silurian Qusaiba shales beneath Hercynian unconformity (after Faqira et al., 2009[10]). MA-I and MA-II show the two areas selected for a 2-D basin modeling study. The Unayzah fields contain oil sourced by Qusaiba shales.

Therefore, only a brief summary is presented in the full paper associated with this Wiki article, and for details the reader is referred to previous publications. The main tectonic phases that shaped the Arabian Plate include:

Figure 2 Generalized pre-Mesozoic stratigraphic column for (A) northwest and (B) east-central Saudi Arabian Basin.
Figure 3 Sedimentary succession and generalized structure in the east-central Arabian Basin (modified from Konert et al., 2001[7]).

As evidenced from the sedimentary succession (Figure 2), throughout the Paleozoic era, clastic continental and shallow-marine sedimentation prevailed on a stable passive margin on the northeastern Gondwana. The Hercynian events of the Carboniferous affected the area, creating regional uplift, widespread erosion, and basement tectonism due to rejuvenation of the preexisting weaknesses in the basement (Konert et al., 2001[7]). From the Permian to the Eocene, the area was a broad stable passive margin where the deposition of mainly shallow-water carbonates with minor anhydrites and shales occurred (Cantrell et al., 2014[11]). Since the Oligocene, the northeastern part of the basin has been undergoing shortening as a consequence of collision of the Arabian Plate with Laurasia (Zagros Orogeny). The resulting flexure of the Arabian Plate underneath the Zagros fold-and-thrust belt created a wedge-shaped, low-angle (less than 2°) foreland basin (Figure 3), that has been the site of mixed evaporitic, carbonate, and clastic sedimentation.

With respect to the Paleozoic Petroleum System (PPS), early Silurian time has prime importance due to deposition of organic-rich (hot) shales in a large shelf area of the Gondwana covering present-day North Africa and the Arabian Peninsula (Klemme and Ulmishek, 1991[12]). Lower Silurian organic-rich (hot) shales have generated about 80–90% of the Paleozoic sourced hydrocarbons in North Africa and the Arabian Peninsula (Klemme and Ulmishek, 1991[12]). The lower hot shales, of the Qusaiba Formation of the Qalibah Group in Saudi Arabia, are major source rocks of the Paleozoic oil and gas accumulations in the Arabian Peninsula (Alsharhan and Nairn, 1997[3]). In most cases, the shales were deposited directly above upper Ordovician periglacial sandstones during the initial early Silurian transgression that was a result of the melting of the late Ordovician ice cap (Lüning et al., 2000[13]).

Figure 4 Petroleum systems of the Arabian Basin (modified after Cantrell et al., 2014[11]).

Petroleum systems

Recently, Cantrell et al. (2014)[11] reviewed the Tethyan Petroleum Systems of Saudi Arabia where they describe two major petroleum systems: the PPS related to the Paleo-Tethys and a Mesozoic Petroleum System (MPS) associated with the Neo-Tethys (Figure 4). The elements of the two petroleum systems (e.g., source, reservoir, and seal characteristics) show significant differences. The PPS is siliciclastic-dominated, whereas the MPS is carbonate-dominated. These two petroleum systems are separated in geological time by the closure of the Paleo-Tethys and the amalgamation of Pangea, followed by subsequent breakup of Pangea and opening of the Neo-Tethys (Cantrell et al., 2014[11]).

The key elements of the MPS are shown in Figure 4. The MPS contains the Jurassic Hanifa and Tuwaiq Mountain Formations as the principal source rocks, with an average resident TOC content of about 3.5 wt.%, and sometimes as high as 14.3 wt.% (Cantrell et al., 2014[11]). The reservoirs extend from the Middle Jurassic to Upper Cretaceous carbonates (the major reservoir being the Arab Formation). Regional seals are provided by Arab anhydrites and the evaporitic Hith Formation. The MPS has been previously discussed in detail (e.g., Carrigan et al., 1994[14]; Cole et al., 1994[15]; Cantrell et al., 2014[11]).

Paleozoic Petroleum Systems: A summary of the PPS is shown in Figure 4. This petroleum system contains the basal Silurian Qusaiba hot shale, and to a lesser extent the Qusaiba warm shales, as its principal source rocks, with reservoirs extending from the Ordovician to the early Triassic. Seals occur at different stratigraphic levels, with the evaporitic Sudair Formation of the early Triassic age serving as the regional top seal of the PPS. Hanadir and Ra’an shales of the Ordovician Qasim Formation may also present some source potential.

Source Rocks: Although several intervals of fine clastics (e.g., shales and mudstone) are potential source rocks of various organic richness, the basal hot shale member of the Qusaiba Formation of the Qalibah Group (Figure 2) shows a basin-wide occurrence (Figure 1) and is organic rich (Cole et al., 1994[15]). Termination of glaciation at the end of the Ordovician resulted in a major sea-level rise during the early Silurian time, leading to deposition of the upward-coarsening progradational Qalibah Group. This rapid transgression caused displacement of earlier shallow marine siliciclastics and resulted in the deposition of organic-rich sediments within anoxic intra-shelf depressions of the northern Gondwana (Jones and Stump, 1999[16]). As these intra-shelf depressions were filled with anoxic sediments, more oxic depositional environment led to a widespread deposition of warm, organic-lean shales of the Qusaiba Formation (Lüning et al., 2000[17]). The organic-rich basal hot shale of the Qusaiba Formation is best developed in the subsurface of east-central Saudi Arabia, as well as in the northwest Saudi Arabia, and has an average TOC content of about 5 wt.%, with maximum values as high as 20 wt.% (Cole et al., 1994[15]). Several Paleozoic oil and gas fields in Saudi Arabia are known to have been sourced from the basal Qusaiba hot shale (AbuAli et al., 1991[18], 1999[19]; Mahmoud et al., 1992[20]; McGillivray and Al-Husseini, 1992[2]; Cole et al., 1994[15]; Jones and Stump, 1999[16]). This hot shale unit contains type II amorphous organic matter, with graptolite and chitinozoans, and ranges in thickness from 10 to 250 ft (3–70 m) as given by Mahmoud et al. (1992)[20], Wender et al. (1998)[4], AbuAli et al. (1999)[19], and AbuAli and Littke (2005)[21]. Within the Qusaiba Formation, a thick sequence of nonradioactive, light to medium gray shale overlies the basal hot shale. This lean shale still contains poor to moderate organic richness (up to a few weight percent TOC) with mixed oil and gas potential (Cole et al., 1994)[15], and due to its thickness, it can also be a volumetrically important source rock for hydrocarbon resources in Saudi Arabia.

Reservoir Rocks: The main reservoirs of the PPS are the sandstones of the Devonian Jauf Formation, sandstones of the Permian Unayzah Formation, and carbonates of the Permian Khuff Formation (Figure 2). The Ordovician Sarah Formation, underlying the regional Qusaiba hot shale source rock, consists mainly of fine- to coarse-grained sandstone sequences of glacial and glacio-fluvial origin. The formation is widely distributed in central and northwestern Saudi Arabia. Cantrell et al. (2014[11]) has noted that pre-Qusaiba clastics (e.g., Sarah sandstones) are generally considered to be tight due to advanced diagenesis, particularly cementation by quartz overgrowths, which has reduced reservoir quality.

Seal Rocks: The PPS contains a number of regional seals. The pre-Qusaiba reservoirs (e.g., the late Ordovician Sarah sandstone Formation) are sealed by the overlying Lower Silurian Qusaiba hot shale. The major regional seals for the Unayzah reservoirs are the transgressive shales and carbonates of the basal Khuff Formation. The Khuff reservoirs are sealed by the evaporite members associated with each carbonate cycle, and the fine clastics of the Sudair Formation are a regional seal for the PPS (Figure 2).

Petroleum Generation and Entrapment: Previous petroleum system and basin modeling studies of the PPS of the east-central part of the Arabian Basin (AbuAli et al., 1999[19]; AbuAli and Littke, 2005[21]) suggested that maturation and oil generation from the Qusaiba basal hot shales commenced as early as the Triassic. Accordingly, early oil expulsion began at about 210 Ma (Triassic), with peak oil expulsion occurring at about 152 Ma (Late Jurassic) and peak gas expulsion at about 140 Ma (Early Cretaceous) (Figure 4).

Based on modeling results, hydrocarbon expulsion from the Silurian hot shale postdated the main phase of trap formation during mid-Carboniferous basin inversion in east-central Saudi Arabia (Figure 4).

The Silurian Qusaiba shales, mainly basal hot shales and possibly, in a limited manner, the overlying warm shales, owing to organic richness and favorable maturity both in the northwest and east-central Arabian Basin, have sourced Paleozoic oil and gas reservoirs and lately have been considered potential target for unconventional resources.

See also

References

  1. Powers, R. W., L. F. Ramirez, D. D. Redmond, and E. L. Elberg Jr., 1966, Geology of the Arabian peninsula, sedimentary geology of Saudi Arabia: USGS Professional Paper 560-D, 150 p.
  2. 2.0 2.1 McGillivray, J. G., and M. I. Al-Husseini, 1992, The Paleozoic petroleum geology of central Arabia: AAPG Bulletin, v. 76, p. 1473–1490.
  3. 3.0 3.1 Alsharhan, A. S. and A. E. M. Nairn, 1997, Sedimentary basins and petroleum geology of the Middle East: Elsevier Science B.V., Amsterdam, 843 p.
  4. 4.0 4.1 Wender, L. E., J. W. Bryant, M. F. Dickens, A. S. Neville, and A. M. Al-Moqbel, 1998, Paleozoic (Pre-Khuff) hydrocarbon geology of the Ghawar Area, eastern Saudi Arabia: GeoArabia, v. 3, p. 273–302.
  5. Al-Hajri, S., and B. Owens, 2000, Sub-surface palynostratigraphy of the Palaeozoic of Saudi Arabia, in S. Al-Hajri and B. Owens, eds., Stratigraphic palynology of the Palaeozoic of Saudi Arabia: GeoArabia Special Publication 1, Gulf PetroLink, Bahrain, p. 10–17.
  6. Al-Husseini, M. I., 2000, Origin of the Arabian plate structures: Amar collision and Najd rift: GeoArabia, v. 5, no. 4, p. 527–542.
  7. 7.0 7.1 7.2 Konert, G., A. M. Afifi, S. A. Al-Hajri, and H. J. Droste, 2001, Paleozoic stratigraphy and hydrocarbon habitat of the Arabian plate: GeoArabia, v. 6, no. 3, p. 407–442.
  8. Sharland, P. R., R. Archer, D. M. Casey, R. B. Davies, S. H. Hall, A. P. Heward, et al. 2001, Arabian plate sequence stratigraphy: GeoArabia Special Publication 2, Gulf PetroLink, Bahrain, 371 p.
  9. Ziegler, M. A., 2001, Late Permian to Holocene paleofacies evolution of the Arabian Plate and its hydrocarbon occurrences: GeoArabia, v. 6, p. 445–504.
  10. 10.0 10.1 Faqira, M., M. Rademakers, and A. M. Afifi, 2009, New insights into the Hercynian orogeny, and their implications for the Paleozoic hydrocarbon system in the Arabian plate: GeoArabia, v. 14, no. 3, p. 199–228.
  11. 11.0 11.1 11.2 11.3 11.4 11.5 11.6 11.7 Cantrell, D. L., P. G. Nicholson, G. W. Hughes, M. A. Miller, A. G. Bhullar, S. T. Abdelbagi et al., 2014, Tethyan petroleum systems of Saudi Arabia, in L. Marlow, C. Kendall, and L. Yose, eds., Petroleum systems of the Tethyan region: AAPG Memoir 106, p. 613–639.
  12. 12.0 12.1 Klemme, H. D., and G. F. Ulmishek, 1991, Effective petroleum source rocks of the world: Stratigraphic distribution and controlling depositional factors: AAPG Bulletin, v. 75, p. 1809–1851.
  13. Lüning, S., J. Craig, D. K. Loydell, P. Storch, and B. Fitches, 2000, Lower Silurian “hot shales” in North Africa and Arabia: Regional distribution and depositional model: Earth Science Reviews, v. 49, p. 121–200.
  14. Carrigan, W. J., G. A. Cole, E. L. Colling, and P. J. Jones, 1994, Geochemistry of the Upper Jurassic Tuwaiq Mountain and Hanifa Formation petroleum source rocks of eastern Saudi Arabia, in B. J. Katz, ed., Petroleum source rocks: Springer-Verlag, New York, p. 67–87.
  15. 15.0 15.1 15.2 15.3 15.4 Cole, G. A., M. A. AbuAli, S. M. Aoudeh, W. J. Carrigan, H. H. Chen, E. L. Colling, et al., 1994, Organic geochemistry of the Paleozoic petroleum system of Saudi Arabia: Energy & Fuels, v. 8, p. 1425–1442.
  16. 16.0 16.1 Jones, P. J., and T. Stump, 1999, Depositional and tectonic setting of the Lower Silurian hydrocarbon source rock facies, Central Saudi Arabia: AAPG Bulletin, v. 83, p. 314–332.
  17. Lüning, S., J. Craig, D. K. Loydell, P. Storch, and B. Fitches, 2000, Lower Silurian “hot shales” in North Africa and Arabia: Regional distribution and depositional model: Earth Science Reviews, v. 49, p. 121–200.
  18. AbuAli, M. A., U. A. Franz, J. Shen, F. Monnier, M. D. Mahmoud, and T. M. Chambers, 1991, Hydrocarbon generation and migration in the Paleozoic sequence of Saudi Arabia: Society of Petroleum Engineers, SPE 21376, p. 345–356.
  19. 19.0 19.1 19.2 AbuAli, M. A., J. L. Rudkiewicz, J. G. McGillivray, and F. Behar, 1999, Paleozoic petroleum system of Central Saudi Arabia: GeoArabia, v. 4, no. 3, p. 321–335.
  20. 20.0 20.1 Mahmoud, M. D., D. Vaslet, and M. I. Al-Husseini, 1992, The Lower Silurian Qalibah Formation of Saudi Arabia: An important hydrocarbon source rock: AAPG Bulletin, v. 76, p. 1491–1506.
  21. 21.0 21.1 AbuAli, M. A., and R. Littke, 2005, Paleozoic petroleum systems of Saudi Arabia: A basin modeling approach: Geo-Arabia, v. 10, no. 3, p. 131–168

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