Paper Titles

Species Composition, Seasonal Dynamics and Distribution of Phytoplankton of the Zaporizke Reservoir
p.1

Study on Web-Site Attributes and Predatory Efficiency of Dark Tetragnathid Spider in Point Calimere Wildlife and Bird Sanctuary
p.11

Biodiversity and Habitat Assessment of Mount Malindawag Naawan, Misamis Oriental, Philippines
p.20

Soil Detoxication by the Means of Activated Carbon in Breeding Process
p.28

Physicochemical Parameter of Palm Oil and Soil from Ihube Community, Okigwe, Imo State Nigeria
p.35

Screening of Different Extracts of Marine Macro Green Algae for Larvicidal Activity against Dengue Fever Mosquito, Aedes aegypti (Diptera: Culiadae)
p.44

Predicting Potential Zones of Hydrocarbon through Seismic Stratigraphy within the Western Barents Sea, Norway
p.52

HomeInternational Letters of Natural SciencesInternational Letters of Natural Sciences Vol. 62Predicting Potential Zones of Hydrocarbon through...

Predicting Potential Zones of Hydrocarbon through Seismic Stratigraphy within the Western Barents Sea, Norway

Article Preview

Abstract:

Stratigraphic play based exploration approach facilitates the development of reservoir prediction models and prospect generation. The present study is carried out along the southern margin of the Loppa High within Hammerfest Basin, Barents Sea, Norway in order to identify the reservoir quality sand in Early Cretaceous age formations along the slope of the high. In this study 2D seismic lines; in which 8 lines are dip and 1 line is strike, and well logs data are interpreted. Outcome is a low-risk exploration technique that is capable of correctly predicting reservoir zones. The stratigraphic trap is identified in the Knurr and Kolje Formations of Adventdalen group, which act as source and seal rock for reservoir respectively. Three stratigraphic surfaces including base of Knurr Formation (sequence boundary), top of Knurr Formation, and Kolje Formation (maximum flooding surface) make a perfect trap for hydrocarbon accumulation. By utilizing the common risk segment analyses, it was identified that the maximum chances of hydrocarbon accumulation are in reservoir zone A and B which lies in up-dip direction.

By email View Pdf

Info:

Periodical:

International Letters of Natural Sciences (Volume 62)

Pages:

52-60

DOI:

https://doi.org/10.56431/p-278vc8

Citation:

Cite this paper

Online since:

March 2017

Authors:

Muhammad Rizwan Mughal, Muhammad Farooq Iqbal*, Irfan Mahmood, Furqan Mahmud Butt, Kalim Ullah

Keywords:

Barents Sea, Common Risk Segment, Reservoir Zones, Seismic Stratigraphy, Stratigraphic Trap

Export:

RIS, BibTeX

Permissions:

Creative Commons CC BY 4.0

Share:

Citation:

* - Corresponding Author

[1] B.P. Tissot, D.H. Welte, Petroleum formation and occurrences, Springer-Verlag, New York, 1978.

[2] K.E. Peters, Guidelines for evaluating petroleum source rock using programmed pyrolysis, The American Association of Petroleum Geologists Bulletin. 70 (1986) 318–329.

DOI: 10.1306/94885688-1704-11d7-8645000102c1865d

[3] A.S. Ratnayake, Y. Sampei, Characterization of organic matter and depositional environment of the Jurassic small sedimentary basins exposed in the northwest onshore area of Sri Lanka, Researches in Organic Geochemistry. 31 (2015) 15–28.

[4] A.S. Ratnayake, Y. Sampei, Preliminary prediction of the geothermal activities in the frontier Mannar Basin, Sri Lanka, Journal of Geological Society of Sri Lanka. 17 (2015) 19–29.

[5] B. Tissot et al., Paleoenvironment and petroleum potential of Middle Cretaceous black shales in Atlantic Basins, The American Association of Petroleum Geologists Bulletin. 64 (1980) 2051–2063.

DOI: 10.1306/2f919738-16ce-11d7-8645000102c1865d

[6] A.S. Pepper, P.J. Corvi, Simple kinetic models of petroleum formation. Part I: oil and gas generation from kerogen, Marine and Petroleum Geology. 12 (1995) 291–319.

DOI: 10.1016/0264-8172(95)98381-e

[7] A.S. Pepper, T.A. Dodd, Simple kinetic models of petroleum formation. Part II: oil-gas cracking, Marine and Petroleum Geology. 12 (1995) 321–340.

DOI: 10.1016/0264-8172(95)98382-f

[8] A.S. Ratnayake, Regionwide geodynamic analyses of the Cenozoic carbonate burial in Sri Lanka related to climate and atmospheric CO2, International Journal of Economic and Environmental Geology. 7 (2016) 1–9.

[9] A.S. Ratnayake, Y. Sampei, C.W. Kularathne, Stratigraphic responses to major depositional events from the Late Cretaceous to Miocene in the Mannar Basin, Sri Lanka, Journal of Geological Society of Sri Lanka. 16 (2014) 5–18.

DOI: 10.1007/s00367-021-00710-x

[10] S.O. Johnsen et al., Outline of the geology of Svalbard, In 7th ESF IMPACT Workshop, 2001.

[11] J.I. Faleide et al., Late Cenozoic evolution of the western Barents Sea-Svalbard continental margin, Global and Planetary Change. 12 (1996) 53–74.

DOI: 10.1016/0921-8181(95)00012-7

[12] D. Worsley, The post‐Caledonian development of Svalbard and the western Barents Sea, Polar Research. 27 (2008) 298–317.

DOI: 10.1111/j.1751-8369.2008.00085.x

[13] N.P. Directorate (Ed.), The Petroleum Resources on the Norwegian Continental Shelf, Norwegian Petroleum Directorate, 1993.

[14] S. Westre, The Askeladden gas find—Troms I. In Petroleum Geology of the North European Margin, Springer Netherlands. (1984) 33–39.

DOI: 10.1007/978-94-009-5626-1_4

[15] S.E. Johansen et al., Hydrocarbon potential in the Barents Sea region: play distribution and potential, Arctic Geology and Petroleum Potential, Norwegian Petroleum Society (NPF), Special Publication. 2 (1992) 273–320.

DOI: 10.1016/b978-0-444-88943-0.50024-1

[16] W.K. Dallmann (Ed.), Lithostratigraphic lexicon of Svalbard: review and recommendations for nomenclature use, Upper Paleozoic to Quaternary bedrock, Norsk Polarinstitut. Tromso, 1999.

[17] C.R. Scotese, L.M. Gahagan, M.I. Ross, Phanerozoic plate tectonic reconstructions. Paleoceanographic mapping project, Institute for Geophysics, University of Texas, Technical Report. 90 (1987).

[18] F.N. Gradstein, J.G. Ogg, A.G. Smith (Eds.), A geologic time scale 2004, Cambridge University Press., Cambridge, 2004.