Evolution of a sand-rich submarine channel–lobe system, and the impact of mass-transport and transitional-flow deposits on reservoir heterogeneity: Magnus Field, Northern North Sea

IF 1.9 4区地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY

Petroleum Geoscience Pub Date : 2021-02-25 DOI:10.1144/petgeo2020-095

M. Steventon, C. Jackson, H. Johnson, D. Hodgson, Sean Kelly, J. Omma, Christine Gopon, C. Stevenson, P. Fitch

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引用次数: 5

Abstract

The geometry, distribution and rock properties (i.e. porosity and permeability) of turbidite reservoirs, and the processes associated with turbidity current deposition, are relatively well known. However, less attention has been given to the equivalent properties resulting from laminar sediment gravity-flow deposition, with most research limited to cogenetic turbidite debrites (i.e. transitional-flow deposits) or subsurface studies that focus predominantly on seismic-scale mass-transport deposits (MTDs). Thus, we have a limited understanding of the ability of subseismic MTDs to act as hydraulic seals, and their effect on hydrocarbon production and/or carbon storage. We investigate the gap between seismically resolvable and subseismic MTDs, and transitional-flow deposits on long-term reservoir performance in this analysis of a small (<10 km-radius submarine fan system), Late Jurassic, sandstone-rich stacked turbidite reservoir (Magnus Field, Northern North Sea). We use core, petrophysical logs, pore fluid pressure, quantitative evaluation of minerals by scanning electron microscopy (QEMSCAN) and 3D seismic-reflection datasets to quantify the type and distribution of sedimentary facies and rock properties. Our analysis is supported by a relatively long (c. 37 years) and well-documented production history. We recognize a range of sediment gravity deposits: (i) thick-/thin-bedded, structureless and structured turbidite sandstone, constituting the primary productive reservoir facies (c. porosity = 22%, permeability = 500 mD); (ii) a range of transitional-flow deposits; and (iii) heterogeneous mud-rich sandstones interpreted as debrites (c. porosity ≤ 10%, volume of clay = 35%, up to 18 m thick). Results from this study show that over the production timescale of the Magnus Field, debrites act as barriers, compartmentalizing the reservoir into two parts (upper and lower reservoir), and transitional-flow deposits act as baffles, impacting sweep efficiency during production. Prediction of the rock properties of laminar- and transitional-flow deposits, and their effect on reservoir distribution, has important implications for: (i) exploration play concepts, particularly in predicting the seal potential of MTDs; (ii) pore-pressure prediction within turbidite reservoirs; and (iii) the impact of transitional-flow deposits on reservoir quality and sweep efficiency. Supplementary material: of data and methods are available at https://doi.org/10.6084/m9.figshare.c.5313860

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富砂海底通道-波瓣系统的演化，以及物质输送和过渡流沉积对储层非均质性的影响：北海北部马格努斯油田

浊积岩储层的几何形状、分布和岩石性质（即孔隙度和渗透率），以及与浊流沉积相关的过程，相对而言是众所周知的。然而，对层流沉积物重力流沉积产生的等效性质的关注较少，大多数研究仅限于同生浊积岩碎屑岩（即过渡流沉积物）或主要关注地震尺度质量传输沉积物（MTD）的地下研究。因此，我们对亚地震MTD作为液压密封的能力及其对碳氢化合物生产和/或碳储存的影响了解有限。我们研究了地震可分辨MTD和次地震MTD之间的差距，以及过渡流沉积物对长期储层性能的影响 km半径的海底扇系），晚侏罗世，富含砂岩的堆叠浊积岩储层（Magnus油田，北海北部）。我们使用岩心、岩石物理测井、孔隙流体压力、扫描电子显微镜（QEMSCAN）对矿物的定量评估和3D地震反射数据集来量化沉积相的类型和分布以及岩石性质。我们的分析得到了一个相对较长的（c.37 年）和有据可查的生产历史。我们认识到一系列沉积物重力沉积：（i）厚/薄层、无结构和结构化的浊积砂岩，构成主要的生产储层相（c.孔隙度 = 22%，渗透率 = 500 mD）；（ii）一系列过渡流沉积物；和（iii）非均质富泥砂岩，解释为碎屑岩（c.孔隙度 ≤ 10%，粘土体积 = 35%，最高可达18 m厚）。这项研究的结果表明，在马格努斯油田的生产时间范围内，碎屑岩充当屏障，将储层划分为两部分（上部和下部储层），过渡流沉积物充当挡板，影响生产过程中的波及效率。层流和过渡流矿床的岩石性质及其对储层分布的影响的预测对以下方面具有重要意义：（i）勘探区块概念，特别是在预测MTD的封闭潜力方面；（ii）浊积岩储层内的孔隙压力预测；以及（iii）过渡流沉积物对储层质量和波及效率的影响。补充材料：有关数据和方法，请访问https://doi.org/10.6084/m9.figshare.c.5313860

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来源期刊

Petroleum Geoscience 地学-地球科学综合

CiteScore

4.80

自引率

11.80%

发文量

审稿时长

>12 weeks

期刊介绍： Petroleum Geoscience is the international journal of geoenergy and applied earth science, and is co-owned by the Geological Society of London and the European Association of Geoscientists and Engineers (EAGE). Petroleum Geoscience transcends disciplinary boundaries and publishes a balanced mix of articles covering exploration, exploitation, appraisal, development and enhancement of sub-surface hydrocarbon resources and carbon repositories. The integration of disciplines in an applied context, whether for fluid production, carbon storage or related geoenergy applications, is a particular strength of the journal. Articles on enhancing exploration efficiency, lowering technological and environmental risk, and improving hydrocarbon recovery communicate the latest developments in sub-surface geoscience to a wide readership. Petroleum Geoscience provides a multidisciplinary forum for those engaged in the science and technology of the rock-related sub-surface disciplines. The journal reaches some 8000 individual subscribers, and a further 1100 institutional subscriptions provide global access to readers including geologists, geophysicists, petroleum and reservoir engineers, petrophysicists and geochemists in both academia and industry. The journal aims to share knowledge of reservoir geoscience and to reflect the international nature of its development.