Natural fractures of the Tuscaloosa marine shale

IF 2.7 3区地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY

AAPG Bulletin Pub Date : 2024-06-01 DOI:10.1306/03052423020

Cristina Mariana Ruse, Mehdi Mokhtari

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引用次数: 0

Abstract

The Tuscaloosa marine shale is an unconventional play whose core area is located in southwestern Mississippi and southeastern Louisiana. Its significance to the energy industry stems from its large oil and gas resources of approximately 1.5 billion bbl of oil (238.5 million m3 of oil) and 4.6 TCF of gas (1.29 billion m3 of gas) and proximity to existing infrastructure. Despite more than 80 wells being hydraulically fractured in the formation, resulting in a total of 13.82 million bbl of oil and 9.04 BCF of gas, challenges remain due to the shale’s high clay content and diverse mineral makeup. Besides, a well-developed network of natural fractures exists across the play, and its effect on hydrocarbon production is yet to be fully understood. This study uses an integrated approach to the characterization of natural fractures in the Tuscaloosa marine shale, incorporating electrical borehole image logs, shear-wave splitting data, and core descriptions from seven wells across the formation. The results show that the identified natural fractures are vertical and subvertical extension fractures, which can be fully mineralized and have heights between 1 and 3 ft (0.31 and 0.91 m). These fractures occur along the east-west direction, are associated with calcite-rich strata, and are capable of transecting the whole borehole. Smaller fractures terminate due to changes in lithology but commonly reactivate in parallel planes. The proposed methodology can help maximize hydraulic fracturing performance across the shale play by identifying stress direction and optimum lateral placement with respect to fracture location. A total of 500 closed fractures are identified in the lateral section of one well. It is also shown that the maximum horizontal stress orientation is consistent throughout the formation and adheres to the general stress trend in the Gulf Coast Basin.

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塔斯卡卢萨海洋页岩的天然裂缝

塔斯卡卢萨海洋页岩是一个非常规油气区，其核心区域位于密西西比州西南部和路易斯安那州东南部。该页岩对能源行业的重要意义在于其蕴藏着大量的石油和天然气资源，石油储量约为 15 亿桶（2.385 亿立方米石油），天然气储量为 4.6 TCF（12.9 亿立方米天然气），而且靠近现有的基础设施。尽管有 80 多口油井在该地层进行了水力压裂，共开采出 1382 万桶石油和 904 亿立方英尺天然气，但由于页岩的粘土含量高且矿物成分多样，挑战依然存在。此外，整个油气区存在发达的天然裂缝网络，其对碳氢化合物生产的影响尚待充分了解。本研究采用综合方法对塔斯卡卢萨海洋页岩中的天然裂缝进行表征，结合了井眼电图像测井、剪切波分裂数据以及来自整个地层七口井的岩心描述。结果表明，已确定的天然断裂为垂直和亚垂直延伸断裂，可完全矿化，高度在 1 至 3 英尺（0.31 至 0.91 米）之间。这些断裂沿东西方向出现，与富含方解石的地层有关，能够横穿整个钻孔。较小的裂缝因岩性变化而终止，但通常在平行平面上重新活化。通过确定应力方向和与裂缝位置相关的最佳横向位置，所提出的方法有助于最大限度地提高整个页岩区的水力压裂性能。在一口油井的横向剖面上共识别出 500 条闭合裂缝。研究还表明，最大水平应力方向在整个地层中是一致的，并与墨西哥湾盆地的总体应力趋势相一致。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

AAPG Bulletin 工程技术-地球科学综合

CiteScore

6.60

自引率

11.40%

发文量

审稿时长

4.8 months

期刊介绍： While the 21st-century AAPG Bulletin has undergone some changes since 1917, enlarging to 8 ½ x 11” size to incorporate more material and being published digitally as well as in print, it continues to adhere to the primary purpose of the organization, which is to advance the science of geology especially as it relates to petroleum, natural gas, other subsurface fluids, and mineral resources. Delivered digitally or in print monthly to each AAPG Member as a part of membership dues, the AAPG Bulletin is one of the most respected, peer-reviewed technical journals in existence, with recent issues containing papers focused on such topics as the Middle East, channel detection, China, permeability, subseismic fault prediction, the U.S., and Africa.