Comparison of elastic anisotropy in the Middle and Upper Wolfcamp Shale, Midland Basin

IF 1.8 3区地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS

Geophysical Prospecting Pub Date : 2024-03-26 DOI:10.1111/1365-2478.13503

Colin M. Sayers, Sagnik Dasgupta

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Abstract

Organic-rich shales contain large amounts of oil and gas and are anisotropic because of fine-scale layering and the partial alignment of organic matter and anisotropic clay minerals with the bedding. An example is the Wolfcamp Shale in the Permian Basin. Elastic anisotropy needs to be accounted for in the characterization of such formations using seismic data and plays a role in hydraulic fracturing and in the evaluation of stress changes and geomechanical effects resulting from production. Using extensive well log data acquired in the Midland Basin, the eastern sub-basin of the Permian Basin, we estimate and compare the elastic anisotropy in the Middle and Upper Wolfcamp Shale by combining data from a vertical pilot well with two lateral wells, one (6SM) drilled in the Middle Wolfcamp and one (6SU) drilled in the Upper Wolfcamp. The data used were acquired at the Hydraulic Fracture Test Site 1, located in the eastern part of the Midland Basin. Thomsen's anisotropy parameter $γ$ calculated from the fast and slow shear sonic is higher on average for the 6SM lateral than for 6SU, consistent with there being less carbonate content in 6SM than in 6SU. However, the anisotropy parameter $γ$ in some regions with higher carbonate content in well 6SU is higher than in well 6SM. This may indicate the influence of natural fractures. The primary set of steeply dipping fractures observed in the lateral wells at Hydraulic Fracture Test Site 1 acts to increase $γ$ if the ratio of the normal-to-shear fracture compliance is less than about 0.5. Sub-horizontal fractures may also increase $γ$ and could affect the vertical extent of hydraulic fractures. Relations between elastic moduli C₃₃ and C₅₅ in the Upper and Lower Wolfcamp in a vertical pilot well allow C₃₃ to be predicted in a lateral well using measurements of C₅₅ in that well. Comparison of Thomsen's anisotropy parameters $γ$ and $ε$ , with $γ$ calculated from the measured values of C₅₅ and C₆₆ and $ε$ calculated from the measured values of C₁₁ and predicted values of C₃₃, show that $ε$ is mostly greater than $γ$ .

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米德兰盆地中上沃尔夫坎普页岩弹性各向异性比较

富含有机质的页岩含有大量石油和天然气，由于细尺度分层以及有机质和各向异性粘土矿物与层理的部分排列，因此具有各向异性。二叠纪盆地的沃尔夫坎普页岩就是一个例子。在利用地震数据描述此类地层的特征时，需要考虑弹性各向异性，弹性各向异性在水力压裂以及评估生产造成的应力变化和地质力学影响方面也发挥着作用。利用在二叠纪盆地东部子盆地米德兰盆地获得的大量测井数据，我们将一口垂直试验井和两口侧向井（一口（6SM）钻于中沃尔夫坎普页岩，一口（6SU）钻于上沃尔夫坎普页岩）的数据结合起来，估算并比较了中沃尔夫坎普页岩和上沃尔夫坎普页岩的弹性各向异性。所使用的数据是在位于米德兰盆地东部的水力压裂试验场 1 获得的。根据快速和慢速剪切声波计算得出的汤姆森各向异性参数，6SM横向平均高于6SU，这与6SM的碳酸盐含量低于6SU一致。然而，在 6SU 井碳酸盐含量较高的一些区域，各向异性参数高于 6SM 井。这可能表明天然裂缝的影响。在水力压裂试验场 1 的侧向井中观察到的主要一组陡斜裂缝，如果法向与剪切裂缝顺应性之比小于 0.5 左右，其作用就会增大。次水平裂缝也可能增加，并可能影响水力压裂的垂直范围。通过垂直试验井中上沃尔夫坎普和下沃尔夫坎普的弹性模量 C33 和 C55 之间的关系，可以利用横向井中的 C55 测量值预测横向井中的 C33。通过比较汤姆森各向异性参数、C55 和 C66 的测量值以及 C11 的测量值和 C33 的预测值，可以发现 C33 大多大于 C55。

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来源期刊

Geophysical Prospecting 地学-地球化学与地球物理

CiteScore

4.90

自引率

11.50%

发文量

118

审稿时长

4.5 months

期刊介绍： Geophysical Prospecting publishes the best in primary research on the science of geophysics as it applies to the exploration, evaluation and extraction of earth resources. Drawing heavily on contributions from researchers in the oil and mineral exploration industries, the journal has a very practical slant. Although the journal provides a valuable forum for communication among workers in these fields, it is also ideally suited to researchers in academic geophysics.