![]() ![]() Onajite E (2013) Seismic data analysis techniques in hydrocarbon exploration. In: Hamimi Z, El-Barkooky A, Martínez Frías J, Fritz H, Abd El-Rahman Y (eds) The geology of Egypt. Moustafa AR, Khalil SM (2020) Structural setting and tectonic evolution of the Gulf of Suez, NW Red Sea and Gulf of Aqaba Rift Systems. Kassem AA, Sen S, Radwan AE, Abdelghany WK, Abioui M (2021) Effect of depletion and fluid injection in the Mesozoic and Paleozoic sandstone reservoirs of the October Oil Field, Central Gulf of Suez Basin: Implications on drilling, production and reservoir stability. Ismail A, Ewida HF, Al-Ibiary MG, Nazeri S, Salama NS, Gammaldi S, Zollo A (2021) The detection of deep seafloor pockmarks, gas chimneys, and associated features with seafloor seeps using seismic attributes in the West offshore Nile Delta. Isaac DB, Abu El Ata AS (2023) Improvement of seismic data quality and recognition of fault discontinuities through seismic data conditioning applications: a case study of Issaran oil field, Gulf of Suez, Egypt. J Pet Explor Prod Technol 13:591–607 Hatton L, Worthington MH, Makin J (1986) Seismic data processing: theory and practice. Gammaldi S, Ismail A, Zollo A (2022) Fluid accumulation zone by seismic attributes and amplitude versus offset analysis at Solfatara Volcano, Campi Flegrei, Italy. Front Earth Sci 10:866534 In: Offshore Mediterranean Conf and Exhibition, Ravenna, Italy, 25– Egypt J Petrol 24(2):203–211įahmi A, El-Tokhy M, Attia A, Saber S, Madkour A (2015) Enhance oil recovery by discovering a new potential hydrocarbon from the unconventional reservoir, in Abu Rudeis/Sidri Field, Gulf of Suez Egypt. Nat Resour Res 29(3):2063–2102Įl Nady MM, Ramadan FS, Hammad MM, Lotfy NM (2015) Evaluation of organic matters, hydrocarbon potential and thermal maturity of source rocks based on geochemical and statistical methods: Case study of source rocks in Ras Gharib oil field, central Gulf of Suez, Egypt. Egypt AAPG Bull 71(10):1274–1293Įl Diasty WS, El Beialy SY, Mostafa AR, Abo Ghonaim AA, Peters KE (2020) Chemometric differentiation of oil families and their potential source rocks in the Gulf of Suez. ![]() SEG Tech Prog Exp Abstr 1984:525–527Ĭhowdhary LR, Taha S (1987) Geology and habitat of oil in Ras Budran field, Gulf of Suez. J Afr Earth Sci 43(1–3):334–378īosworth W, El-Hawat AS, Helgeson DE, Burke K (2008) Cyrenaican “shock absorber” and associated inversion strain shadow in the collision zone of northeast Africa. Mém Mus Natl Hist Nat 1993(186):567–606īosworth W, Huchon P, McClay K (2005) The Red Sea and Gulf of Aden basins. Cambridge University Press, Cambridge, p 212īosworth W, McClay KR (2001) Structural and stratigraphic evolution of the Gulf of Suez rift, Egypt: a synthesis. Egypt AAPG Bull 87(1):143–180īacon M, Simm R, Redshaw T (2003) 3-D seismic interpretation. NRIAG J Astron Geophys 11(1):337–354Īlsharhan AS (2003) Petroleum geology and potential hydrocarbon plays in the Gulf of Suez rift basin. NRIAG J Astron Geophys 9(1):38–51Īl-Heety AJR, Thabit HA (2022) Random and coherent noise attenuation for 2D land seismic reflection line acquired in Iraq. Accordingly, previously interpreted subsurface structures can be more precisely delineated and identified when the prior methodology is applied to the original seismic data of the Rabeh East Field.Ībdel Fattah TH, Diab A, Younes M, Ewida H (2020) Improvement of Gulf of Suez subsurface image under the salt layers through re-processing of seismic data-a case study. ![]() Time-variant scaling was avoided for the stacked amplitudes to preserve the real amplitudes instead, automatic gain control, which amplifies weak reflections, was used. The Ormsby filter was applied to optimize the ratio of signal to noise to a good extent. The noise at high and low frequencies was subsequently eliminated using band-pass filtering. The resulting sections showed significant improvements in vertical resolution, sharpness, and continuity, yielding better-characterized reflectors. Deconvolution was applied after the stack to decrease reverberations and short-period multiples and to recover high frequencies that common midpoint (CMP) stacking attenuates. The designed processing sequence included a step for reducing noise from random sources using deconvolution. The technique was applied to 20 seismic lines in the study area to improve the seismic imaging and increase the signal-to-noise ratio and thus obtain more accurate interpretations. This will help in obtaining seismic sections of better quality for the petroleum exploration process. ![]() The main objective of this research was to perform noise reduction for post-stack seismic data from the Rabeh East Oil Field, southern Gulf of Suez Basin. This noise prevents the accurate imaging of seismic sections and lead to mistakes in their interpretations. Seismic data are usually contaminated with random and coherent noise. ![]()
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