Assessment of pore pressure in the Oligocene–Pleistocene stratigraphy of the West Delta Deep Marine, offshore Nile Delta, Egypt

IF 1.6 4区 地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS Marine Geophysical Research Pub Date : 2024-01-23 DOI:10.1007/s11001-023-09536-x
Sherif Farouk, Souvik Sen, Fayez Ahmad, Khaled Al-Kahtany, Salim Benmamar, Ahmed Abdeldaim
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Abstract

One of the main drilling challenges in the offshore deep-water Nile Delta is the overpressured Tertiary shales, which causes formation fluid influxes, kicks, and very narrow drilling window, thus contributes to non-productive times and enhanced drilling risk. Accurate understanding of pore pressure distribution is crucial for casing design, mud optimization and safe and successful drilling. This study presents first ever in-depth analysis of the pore pressure distribution within the 4500 m thick Oligocene-Pleistocene stratigraphy from the West Delta Deep Marine block in deep-water Nile Delta. Direct formation pressure measurements indicated around 0.06–0.1 PSI/ft (1.36–2.26 MPa/km) gas gradient in the Pliocene El Wastani and Kafr El Sheikh sandstone reservoirs, while the Miocene Qantara sandstones are water-bearing with a 0.42 PSI/ft (9.5 MPa/km) pressure gradient. Shale porosity distribution exhibited additional porosity retention within the montmorillonite and mixed clay-dominated Late Pliocene and deeper sediments and marks the onset of overpressure at the top Kafr El Sheikh Formation. Based on the loading trends and acoustic slowness-density relationship, we inferred compaction disequilibrium as the primary overpressure generating mechanism resulted from high sedimentation rate. Shale pore pressure was interpreted by utilizing wireline logs by utilizing compaction trendline-based approach and calibrated with drilling events and mudlog data. Qantara and Tineh formations are characterized by 0.75–0.77 PSI/ft (16.96–17.41 MPa/km) pore pressure gradient leaving a narrow drilling mud window of 1.7–2 PPG. Based on vertical effective stresses, two significant overpressure compartments were identified in the Late Pliocene and Early Miocene-Late Oligocene, which were separated by the Middle Miocene Sidi Salem Formation acting as a pressure seal.

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评估埃及尼罗河三角洲近海西三角洲深海区渐新世-早更新世地层中的孔隙压力
尼罗河三角洲近海深水区的主要钻井挑战之一是第三纪页岩的超压,这会导致地层流体涌入、磕碰和钻井窗口非常狭窄,从而导致非生产时间和钻井风险增加。准确了解孔隙压力分布对于套管设计、泥浆优化以及安全成功钻井至关重要。本研究首次深入分析了尼罗河三角洲深水区块西三角洲深海 4500 米厚渐新世-早更新世地层中的孔隙压力分布。直接地层压力测量结果表明,在上新世的 El Wastani 和 Kafr El Sheikh 砂岩储层中,气体梯度约为 0.06-0.1 PSI/ft(1.36-2.26 MPa/km),而中新世的 Qantara 砂岩含水,压力梯度为 0.42 PSI/ft(9.5 MPa/km)。页岩孔隙度分布显示,在以蒙脱石和混合粘土为主的晚更新世及更深层沉积物中,有更多的孔隙度保留,这标志着 Kafr El Sheikh 地层顶部开始出现超压。根据负载趋势和声学慢度-密度关系,我们推断压实失衡是高沉积速率导致的主要超压产生机制。页岩孔隙压力的解释是利用基于压实趋势线的有线测井记录,并与钻井事件和泥浆记录数据进行校准。Qantara 和 Tineh 地层的孔隙压力梯度为 0.75-0.77 PSI/ft(16.96-17.41 MPa/km),钻井泥浆窗口较窄,为 1.7-2 PPG。根据垂直有效应力,在晚上新世和早中新世-晚渐新世确定了两个重要的超压区,这两个超压区被作为压力封层的中中新世西迪-萨利姆地层分隔开来。
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来源期刊
Marine Geophysical Research
Marine Geophysical Research 地学-地球化学与地球物理
CiteScore
2.80
自引率
14.30%
发文量
41
审稿时长
>12 weeks
期刊介绍: Well-established international journal presenting marine geophysical experiments on the geology of continental margins, deep ocean basins and the global mid-ocean ridge system. The journal publishes the state-of-the-art in marine geophysical research including innovative geophysical data analysis, new deep sea floor imaging techniques and tools for measuring rock and sediment properties. Marine Geophysical Research reaches a large and growing community of readers worldwide. Rooted on early international interests in researching the global mid-ocean ridge system, its focus has expanded to include studies of continental margin tectonics, sediment deposition processes and resulting geohazards as well as their structure and stratigraphic record. The editors of MGR predict a rising rate of advances and development in this sphere in coming years, reflecting the diversity and complexity of marine geological processes.
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