Flexural Shear Associated with Transpressional Folding of Abu Dhabi Onshore Fields
Abstract: The Abu Dhabi onshore Anticlinal Fields are trending NE-SW and N-S, with their eastern flanks being of steeper dip (~3°-5°) than their western flanks (~1°-2°). In previous research, kinematics, and mechanics of onshore Abu Dhabi folded anticlines had not been addressed. The main objective of this paper is to understand the kinematics and mechanics of the folding systems.A new approach to understanding the mechanical evolution of these anticlines is presented here through the use of conceptual modelling and the… Show more
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Cited by 3 publications
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Hydrocarbon migration pathways control the distribution of oil and gas in Abu Dhabi sedimentary basins and therefore it is one of the most important and controversial problems in petroleum system pillars. The complexity of this problem appears in full of regards to the faults and fractures, as most of them are cemented, while the bedding planes forming corridors that are playing an important role in turn. Therefore, it is necessary to identify the direction, dominant form, and distance of oil migration. The role of bedding corridors in migration of hydrocarbon was not fully estimated. This paper introduces the bedding corridors as an important migration pathway in Abu Dhabi. They are sub-horizontal tabular bodies of bedding plane weak zones formed as shear swarms, which vertically divide the entire reservoir thickness and extend laterally as their layers. Bedding corridors are genetically related to shearing along the bedding surfaces and they contribute to the conductive systems in Abu Dhabi reservoirs. Bedding corridors can be best identified from horizontal borehole image logs, and as spikes in open-hole logs. An integrated study comprising logs, cores and outcrops are the main sources to delineate them. The significance of this approach is that once a diagnostic signature can be recognized in open-hole logs, in combination with lost circulation data, it can be used to allocate bedding corridors in other vertical wells with no image logs. Results indicate that the horizontal stress anisotropy is the key parameter to predict bedding corridors behavior under different stress regimes, as the Shmin and SHmax is usually very close to each other in most of Abu Dhabi reservoirs. Swapping stresses with depth is common in Abu Dhabi fields, where a strike-slip regime can open and dilate the shear stress along the bedding planes. Strike slip faulting regime, wich prevailed Abu Dhabi reservoirs is the main source of the stresses that distribute along the bedding planes, where most of the stresses are dissipating horizontally comprising the strike slip component. Bedding corridors can be considered as indicators of the reservoir stress history, where they form extraordinary clusters of a huge number of shear conductive corridors in a transpressional regime. In Abu Dhabi oil and gas reservoirs, bedding corridors networks help drain hydrocarbons. In carbonate formations, for example, it is quite common to observe a permeability contrast of about 500mD or more between the rock matrix and surrounding bedding corridors. In this paper, we differentiate between image-log porosity and density-neutron porosity, which is regarded as secondary porosity attributable to bedding corridors. We also introduce here a working hypothesis about their effect on hydrofraccing being part of geomechanical assessment. Geomechanically, these corridors can be used efficiently to increase production particularly in tight and unconventional reservoirs. The role of bedding corridors is particularly important in reservoirs having a tight matrix. It is recommended horizontal drilling to maximize production through those bedding corridors compared to vertical wells. Even in fraccing design, there is a need to highlight the importance of bedding planes in helping fracs to propagate.
Hydrocarbon migration pathways control the distribution of oil and gas in Abu Dhabi sedimentary basins and therefore it is one of the most important and controversial problems in petroleum system pillars. The complexity of this problem appears in full of regards to the faults and fractures, as most of them are cemented, while the bedding planes forming corridors that are playing an important role in turn. Therefore, it is necessary to identify the direction, dominant form, and distance of oil migration. The role of bedding corridors in migration of hydrocarbon was not fully estimated. This paper introduces the bedding corridors as an important migration pathway in Abu Dhabi. They are sub-horizontal tabular bodies of bedding plane weak zones formed as shear swarms, which vertically divide the entire reservoir thickness and extend laterally as their layers. Bedding corridors are genetically related to shearing along the bedding surfaces and they contribute to the conductive systems in Abu Dhabi reservoirs. Bedding corridors can be best identified from horizontal borehole image logs, and as spikes in open-hole logs. An integrated study comprising logs, cores and outcrops are the main sources to delineate them. The significance of this approach is that once a diagnostic signature can be recognized in open-hole logs, in combination with lost circulation data, it can be used to allocate bedding corridors in other vertical wells with no image logs. Results indicate that the horizontal stress anisotropy is the key parameter to predict bedding corridors behavior under different stress regimes, as the Shmin and SHmax is usually very close to each other in most of Abu Dhabi reservoirs. Swapping stresses with depth is common in Abu Dhabi fields, where a strike-slip regime can open and dilate the shear stress along the bedding planes. Strike slip faulting regime, wich prevailed Abu Dhabi reservoirs is the main source of the stresses that distribute along the bedding planes, where most of the stresses are dissipating horizontally comprising the strike slip component. Bedding corridors can be considered as indicators of the reservoir stress history, where they form extraordinary clusters of a huge number of shear conductive corridors in a transpressional regime. In Abu Dhabi oil and gas reservoirs, bedding corridors networks help drain hydrocarbons. In carbonate formations, for example, it is quite common to observe a permeability contrast of about 500mD or more between the rock matrix and surrounding bedding corridors. In this paper, we differentiate between image-log porosity and density-neutron porosity, which is regarded as secondary porosity attributable to bedding corridors. We also introduce here a working hypothesis about their effect on hydrofraccing being part of geomechanical assessment. Geomechanically, these corridors can be used efficiently to increase production particularly in tight and unconventional reservoirs. The role of bedding corridors is particularly important in reservoirs having a tight matrix. It is recommended horizontal drilling to maximize production through those bedding corridors compared to vertical wells. Even in fraccing design, there is a need to highlight the importance of bedding planes in helping fracs to propagate.
Abu Dhabi fields profitable development starts with understanding structural framework and styles kinematically and dynamically in the context of regional and local exploration resource potential evaluation. This enables to determine and predict the structural controls on deposition and understand the nature and development of trap styles. The fault systems in Abu Dhabi fields investigating the different stages of geometrically, kinematically and dynamically development of strike-slip basins. The seismically mapped stratigraphic succession starts with the Permian, that showing fault systems characterized by Late Mesozoic transpressional wrench tectonics. Abu Dhabi mature basins provide important information on the temporal and spatial changes in sediment source, depositional systems, and uplift history of Abu Dhabi fields. A gap is existing between the faults systems interpreted on the magnetic maps that showing NE lineaments and the Permian-Tertiary succession with main faults tending due NW. Below the deeper Permian interpreted horizons and up to the basement is not clear in Abu Dhabi, as the seismic is not cover the deeper section. Therefore, a tectonic model is required that captured the unknown using the known faulting relations with the depositional and deformed rock units. This work is a multi-disciplined investigation of the complex spatial and temporal relationships between facies distribution and faulting, which exist during basin evolution in a tectonically active intracontinental setting. This exciting field-based study will integrate structural mapping, structural techniques, and seismic interpretation to examine the diverse origins of strike-slip related basins in the UAE. The aim of the fieldwork was to gain a three-dimensional picture for the tectonic system that has operated in Abu Dhabi basins through time, and to understand the interplay between faulting, basin margin deformation, facies distribution, architecture, and adjacent mountain building. Kinematic analysis of faults for stress determination was carried out on Permian up to Tertiary rocks, which revealed various transtensional and/or transpressional regime. Abu Dhabi deformation was segregated into two coeval distinctive states of stress. The Permian-Cretaceous state of stress was compressional, with σ1 oriented in a NW-SE direction and changed by the Tertiary to be due NE. This paper address generating reliable distributions of the deformation zones predictions that can impact the reservoir parameters geodynamically within onshore/offshore Abu Dhabi successions where the development induced modifications and their effects on reservoir permeability can be understood and managed.
The sector screening review is a surveillance tool used to assess and find opportunities to increase the oil production and improve the performance of the reservoir. We developed a novel interdisciplinary workflow (geology-engineering) integrating dynamic and static data in order to generate opportunities at well and field level; this methodology was used to analyze the impact of fractures in the reservoir performance and management. The complexity of the geology on areas near a graben system (structure at center of the field with biggest vertical displacement) was suspected to cause flow anomalies that ultimately affected the well productivity indexes. After an exhaustive evaluation, it was noticed that a well showed lower productivity index (PI), 2-3 times less than nearby producers in the area, same reservoir Unit Z2 (similar lengths, conditions). To understand the root cause of such performance, a geoengineering workflow was implemented, integrating pressure transient analyses (PTA), production logging (PLT), bottom hole image (BHI), seismic (exceptionally complete dataset) and extrapolated to other wells with similar behavior. The PLT showed that 70% of the well contribution was concentrated in only a small interval of the horizontal section, this interval was correlated to a conductive fault through BHI, which was also detected by seismic (correlates with low velocity anomaly). The PTA showed unexpected pressure transient behavior suspected to be related to the dynamic effect of the fault and associated fractures. Learnings from above analyses triggered actions in different scales/stages: at Well scale, 1st Stage: the well was selected to be completed using selective stimulation with abrasive jet, to remove damage of the first 400 ft. of the well (skin factor masked by fracture contribution) and unlock the potential of non-contributing zone (after fault, to toe); allowing the well to produce 25% additional oil and doubling the PI. 2nd Stage (planned): workover proposal to install lower completion (LC), to ensure even depletion, avoid by-passed oil and prevent early water/gas breakthrough. Field scale: new wells to be drilled in reservoir zones potentially affected by the graben will be equipped with LC. Finally, a geological well testing framework matching the PBU and PLT was implemented based on a high resolution geological model designed to capture the properties of the matrix and fractures. The results from this study were used as diagnostic tool for additional wells with similar conditions which lack PLT data. Noticeably, the presence of flow controlling fractures was usually suspected but not properly assessed/quantified in this reservoir, mainly due to the fact that the dynamic impact of these fractures was masked by the overlapping of different geological phenomena. The implementation of our geological-engineering workflow allowed immediately triggering actions that could lead to major performance enhancements at field- and well-level, including field development, management and modelling practices in such complex geological arquitectures.
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