Importance of Preexisting Fractures to Completion and Production Efficiencies in the Marcellus Shale Energy and Environmental Lab MSEEL

Author:

Carr Timothy1,Fathi Ebrahim1,Bohn Rob2,Adenan Mohammad Faiq1,Li Liwei1,Panetta Brian1,Carney B. J.3,Mitchell Natalie1

Affiliation:

1. West Virginia University

2. Silixa

3. Northeast Natural Energy, LLC

Abstract

Abstract The Marcellus Shale Energy and Environmental Lab (MSEEL) provides a publicly available dataset and a hypothesis-driven field test of the significance of preexisting natural fractures at multiple scales on the effectiveness of the stimulation of an unconventional reservoir. Sonic and microresistivity imaging show the presence of numerous preexisting cemented fracture swarms, which are evaluated in terms of their influence on the fracture stimulation. Natural fracture intensity in the Boggess 5H and MIP-3H were interpreted based on wireline and logging while drilling (LWD) image logs showing that 1000's of calcite and bitumen cemented, but relatively weak, fractures are present along the laterals as swarms that are at an angle to the present-day stress regime. Fractures with complex bitumen and calcite filling were recognized in cores from pilot wells at the micro and macroscales (micron to millimeter). The importance of pre-existing fractures on geometric stimulations was evaluated and compared to cluster locations that avoided intense preexisting fractures using fiber-optic distributed acoustic and distributed temperature sensing (DAS/DTS) data and supported by production and simulation. Fiber-optic DTS and DAS measurements were coupled with wireline and LWD image logs from the lateral to recognize preexisting and cemented fractures. This data is supplemented with core analysis including (CT and thin sections) from vertical pilot wells shows that clusters in parts of a stage dominated by preexisting fractures have significantly more hydraulic fracture activity to the point that other clusters appear largely inactive. In addition, processed fiber-optic data indicates that preexisting fractures can form near-well bore leak-off pathways to previous stimulated stages. Both can lead to stimulation and subsequent production inefficiencies. Two wells (Boggess 1H and 3H) that attempted to avoid preexisting fractures showed a significant increase in fracture stimulated volume based on decline curve analysis and microseismic. Production history and simulated future production support the conclusion that avoiding preexisting fractures in the Marcellus Shale can increase estimate ultimate production. We present conclusions about stage and cluster spacing and the significance of preexisting natural fractures on stage isolation and fracture efficiency. The publically available data and workflow allow others to use, verify, and evaluate our findings using the same initial data.

Publisher

SPE

Reference13 articles.

1. Amini, S., Kavousi, P., and CarrT. R. 2017. "Application of Fiber-Optic Temperature Data Analysis in Hydraulic Fracturing Evaluation–A Case Study in Marcellus Shale." In Proceedings of the 5th Unconventional Resources Technology Conference. Tulsa, OK, USA: American Association of Petroleum Geologists. https://doi.org/10.15530/urtec-2017-2686732.

2. Barree, R. D., and Miskimins, J. L. 2015. "Calculation and Implications of Breakdown Pressures in Directional Wellbore Stimulation." In SPE Hydraulic Fracturing Technology Conference, 10:148–55; discussion 156. Society of Petroleum Engineers. https://doi.org/10.2118/173356-MS.

3. Bohn, R., Hull, R., Trujillo, K., Wygal, B., Parsegov, S. G., Carr, T. R., Carney, B.J. 2020. Study of The Marcellus Shale Energy and Environmental Lab (MSEEL) Completion Designs Using Fracture Modeling, Proceedings Unconventional Resources Technology Conference (URTeC https://library.seg.org/doi/10.15530/urtec-2020-2440,19p.

4. Carr, T. R., Wilson, T.H., Kavousi, P., Amini, S., Sharma, S., Hewitt, J., Costello, I., Carney, B. J., Jordon, E., Malcolm Yates, M., MacPhail, K., Uschner, N., Thomas, M., Akin, S., Magbagbeola, O., Morales, A., Johansen, A., Hogarth, L., Anifowoshe, O., Naseem, K., Hammack, R., Kumar, A., Zorn, E., Vagnetti, R., and Crandall, D. 2017. Insights from the Marcellus Shale Energy and Environment Laboratory (MSEEL), Proceedings, Unconventional Resources Technology Conference (URTeC), p. 1130–1142. https://doi.org/10.15530/URTEC-2017-2670437

5. Microearthquakes Associated with Long Period, Long Duration Seismic Events During Stimulation of a Shale Gas Reservoir;Das;SEG Technical Program Expanded Abstracts 2012,2012

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