Abstract
The Messinian Abu Madi Formation represents the most prospective reservoir target in the Nile Delta. Hydrocarbon exploration endeavors in Nile Delta over the last few decades highlighted some uncertainties related to the predictability and distribution of the Abu Madi best reservoir quality facies. Therefore, this study aims at delineating the factors controlling the petrophysical heterogeneity of the Abu Madi reservoir facies in Faraskour Field, northeastern onshore part of the Nile Delta. This work provides the very first investigation on the reservoir properties of Abu Madi succession outside the main canyon system. In the study area, Abu Madi reservoir is subdivided into two sandstone units (lower fluvial and upper estuarine). Compositionally, quartzose sandstones (quartz > 65%) are more common in the fluvial unit, whereas the estuarine sandstones are often argillaceous (clays > 15%) and glauconitic (glauconite > 10%). The sandstones were classified into four reservoir rock types (RRTI, RRTII, RRTIII, and RRTIV) having different petrophysical characteristics and fluid flow properties. RRTI hosts the quartzose sandstones characterized by mega pore spaces (R35 > 45 µm) and a very well-connected, isotropic pore system. On the other side, RRTIV constitutes the lowest reservoir quality argillaceous sandstones containing meso- and micro-sized pores (R35 > 5 µm) and a pore system dominated by dead ends. Irreducible water saturation increases steadily from RRTI (Swir ~ 5%) to RRTIV (Swir > 20%). Additionally, the gas–water two-phase co-flowing characteristics decrease significantly from RRTI to RRTIV facies. The gaseous hydrocarbons will be able to flow in RRTI facies even at water saturation values exceeding 90%. On the other side, the gas will not be able to displace water in RRTIV sandstones even at water saturation values as low as 40%. Similarly, the influence of confining pressure on porosity and permeability destruction significantly increases from RRTI to RRTIV. Accordingly, RRTI facies are the best reservoir targets and have high potentiality for primary porosity preservation.
Highlights
The Nile Delta with its recent giant onshore and offshore gas discoveries (e.g., Zohr, Noras) is currently proven as the most prolific gas province in North Africa (e.g., Esestime et al 2016)
The stratigraphic position of this unconformity, its morphology and seismic–stratigraphic characteristics coincide with the bottom erosion surface (BES) which documents the boundary between the pre-Messinian salinity crisis (MSC) and syn, post-MSC facies along the entire Mediterranean (Lofi et al 2011a, b; Pigott and Abdel-Fattah 2014; Leila and Moscariello 2019)
The BES is onlapped by vertically variable amplitude seismic reflections which comprise the syn-MSC Abu Madi facies that infilled the subaerial canyons during the late intra-Messinian transgression
Summary
The Nile Delta with its recent giant onshore and offshore gas discoveries (e.g., Zohr, Noras) is currently proven as the most prolific gas province in North Africa (e.g., Esestime et al 2016). The clay-rich successions of the Kafr El-Sheikh Formation constitute the main source of biogenic gases in the Nile Delta onshore region (Vandre et al 2007). Offshore Nile Delta, the Miocene (Tineh, Qantara, Sidi Salem and Wakar) and Pliocene (Kafr El-Sheikh) shales are proven sources for the biogenic gases (Vandre et al 2007; Esestime et al 2016)
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