Evaluation on the anisotropic brittleness index of shale rock using geophysical logging

Junchuan Gui; Jianchun Guo; Yu Sang; Yaxi Chen; Tianshou Ma; P.G. Ranjith

doi:10.1016/j.petlm.2022.06.001

Petroleum ›› 2023, Vol. 9 ›› Issue (4) :545 -557. DOI: 10.1016/j.petlm.2022.06.001

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Evaluation on the anisotropic brittleness index of shale rock using geophysical logging

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Abstract

The brittleness index plays a significant role in the hydraulic fracturing design and wellbore stability analysis of shale reservoirs. Various brittleness indices have been proposed to characterize the brittleness of shale rocks, but almost all of them ignored the anisotropy of the brittleness index. Therefore, uniaxial compression testing integrated with geophysical logging was used to provide insights into the anisotropy of the brittleness index for Longmaxi shale, the presented method was utilized to assess brittleness index of Longmaxi shale formation for the interval of 3155-3175 m in CW-1 well. The results indicated that the brittleness index of Longmaxi shale showed a distinct anisotropy, and it achieved the minimum value at β = 45°-60°. As the bedding angle increased, the observed brittleness index (BI_{2_}_β) decreased firstly and increased then, it achieved the lowest value at β = 40°-60°, and it is consistent with the uniaxial compression testing results. Compared to the isotropic brittleness index (β = 0°), the deviation of the anisotropic brittleness index ranged from 10% to 66.7%, in other words, the anisotropy of brittleness index cannot be ignored for Longmaxi shale. Organic matter content is one of the main intrinsic causes of shale anisotropy, and the anisotropy degree of the brittleness index generally increases with the increase in organic matter content. The present work is valuable for the assessment of anisotropic brittleness for hydraulic fracturing design and wellbore stability analysis.

Keywords

Shale rock / Brittleness / Brittleness index / Anisotropy / Transverse isotropy / Geophysical logging

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Junchuan Gui, Jianchun Guo, Yu Sang, Yaxi Chen, Tianshou Ma, P.G. Ranjith. Evaluation on the anisotropic brittleness index of shale rock using geophysical logging. Petroleum, 2023, 9(4): 545-557 DOI:10.1016/j.petlm.2022.06.001

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Acknowledgments

This work was supported by the post-doctoral project of Petrochina Southwest Oil & Gas Field Company “Research on Deep Shale Geomechanics and Effective Fracturing Factors” (Grant No. 20210302-31), the Program of Introducing Talents of Discipline to Chinese Universities (111 Plan) (Grant No. D18016), the Sichuan Science and Technology Program (Grant No. 2020JDJQ0055), the Nanchong-SWPU Science and Technology Strategic Cooperation Foundation (Grant No. SXHZ033), the Youth Scientific and Technological Innovation Team Foundation of SWPU (Grant No. 2019CXTD09).

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