Regional In-Situ Stress Prediction in Frontier Exploration and Development Areas: Insights from the First-Ever 3D Geomechanical Model of the Arabian Plate

R. Goteti, Y. Alzayer, H. Baek, Yanhui Han
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Abstract

In this paper, we present results from the first-ever 3D geomechanical model that supports pre-drill prediction of regional in-situ stresses throughout the Arabian Plate. The results can be used in various applications in the petroleum industry such as fault slip-tendency analysis, hydraulic fracture stimulation design, wellbore stability analysis and underground carbon storage. The Arabian tectonic plate originated by rifting of NE Africa to form the Red Sea and the Gulfs of Aden and Aqaba. The continental rifting was followed by the formation of collisional zones with eastern Turkey, Eurasia and the Indo-Australian Plate, which resulted in the formation of the Eastern Anatolian fault system, the fold-thrust belts of Zagros and Makran, and the Owen fracture zone. This present-day plate tectonic framework, and the ongoing movement of the Arabian continental lithosphere, exert a first-order control on the of in-situ stresses within its sedimentary basins. Using data from published studies, we developed a 3D finite element of the Arabian lithospheric plate that takes into account interaction between the complex 3D plate geometry and present-day plate boundary velocities, on elastic stress accumulation in the Arabian crust. The model geometry captures the first-order topographic features of the Arabian plate such as the Arabian shield, the Zagros Mountains and sedimentary thickness variations throughout the tectonic plate. The model results provide useful insights into the variations in in-situ stresses in sediments and crystalline basement throughout Arabia. The interaction between forces from different plate boundaries results in a complex transitional stress state (thrust/strike-slip or normal/strike-slip) in the interior regions of the plate such that the regional tectonic stress regime at any point may not be reconciled directly with the anticipated Andersonian stress regimes at the closest plate boundary. In the sedimentary basin east of the Arabian shield, the azimuths of the maximum principal compressive stresses change from ENE in southeast to ~N-S in northern portions of the plate. The shape of the plate boundary, particularly along the collisional boundaries, plays a prominent in controlling both the magnitude and orientations of the principal stresses. In addition, the geometry of the Arabian shield in western KSA and variations in the sedimentary basin thickness, cause significant local stress perturbations over 10 – 100 km length scales in different regions of the plate. The model results can provide quantitative constraints on relative magnitudes of principal stresses and horizontal stress anisotropy, both of which are critical inputs for various subsurface applications such as mechanical earth model (MEM) and subsequently wellbore stability analysis (WSA). The calibrated model results can potentially reduce uncertainties in input stress parameters for MEM and WSA and offer improvements over traditional in-situ stress estimation techniques.
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前沿勘探和开发地区的区域地应力预测:来自阿拉伯板块首次三维地质力学模型的见解
在本文中,我们展示了有史以来第一个3D地质力学模型的结果,该模型支持整个阿拉伯板块区域地应力的钻前预测。其结果可用于断层滑移倾向分析、水力压裂增产设计、井筒稳定性分析和地下储碳等石油工业中的各种应用。阿拉伯构造板块起源于非洲东北部的裂谷,形成红海、亚丁湾和亚喀巴湾。大陆裂陷后,与土耳其东部、欧亚大陆和印澳板块形成碰撞带,形成了东安纳托利亚断裂体系、扎格罗斯和马卡伦褶皱冲断带和欧文断裂带。现今的板块构造格局和阿拉伯大陆岩石圈的持续运动对其沉积盆地内的地应力起着一级控制作用。利用已发表的研究数据,我们开发了阿拉伯岩石圈板块的三维有限元,考虑了复杂的三维板块几何形状和当今板块边界速度之间的相互作用,以及阿拉伯地壳的弹性应力积累。模型几何捕捉了阿拉伯板块的一级地形特征,如阿拉伯盾、扎格罗斯山脉和整个构造板块的沉积厚度变化。模型结果为整个阿拉伯地区沉积物和结晶基底的地应力变化提供了有用的见解。来自不同板块边界的力之间的相互作用导致了板块内部复杂的过渡应力状态(逆冲/走滑或正向/走滑),以至于任何一点的区域构造应力状态都可能与最近板块边界预期的安德森应力状态不直接协调。在阿拉伯盾构以东的沉积盆地中,最大主压应力方位角由东南ENE向北~南北向变化。板块边界的形状,特别是沿碰撞边界的形状,在控制主应力的大小和方向方面起着突出的作用。此外,KSA西部阿拉伯盾的几何形状和沉积盆地厚度的变化,在板块的不同区域造成了10 - 100公里长度尺度上的显著局部应力扰动。模型结果可以提供主应力和水平应力各向异性的相对大小的定量约束,这两者都是各种地下应用的关键输入,例如力学地球模型(MEM)和随后的井筒稳定性分析(WSA)。校准后的模型结果可以潜在地减少MEM和WSA输入应力参数的不确定性,并对传统的地应力估计技术进行改进。
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