Utah FORGE Project 3-2417: Simulations for Distributed Acoustic Sensing Strain Signatures as an Indicator of Fracture Connectivity
This dataset encompasses simulations of strain signatures from both hydraulically connected and "near-miss" fractures in enhanced geothermal systems (EGS). The files and results are presented from the perspective of digital acoustic sensing's (DAS) potential to differentiate the two fracture types. This dataset was acquired by the FOGMORE R&D project (Fiber Optic Geophysical MOnitoring of Reservoir Evolution), under Utah FORGE R&D Project 3-2417. Included are simulation and results via MatLab and COMSOL files, as well as a thesis and paper summarizing the results.
Some stimulated fractures may be incomplete, approaching but not intersecting the production well. These "near-miss" fractures can be addressed in future stimulation stages or re-stimulated to complete the connection. We propose the use of fiber optic distributed acoustic sensing (DAS) as a method by which near-miss stimulated fractures may be identified and distinguished from hydraulically connected fractures. The low-frequency sub-nanostrain signatures of both complete and near-miss fractures in DAS data are simulated in this study using a hydrogeomechanical discrete fracture network model. The spatial distribution of strain was found to be an accurate indicator. However, this indicator must be evaluated in the context of DAS gauge length and spatial sampling. These simulations are a precursor to tests conducted at FORGE in 2023.
Citation Formats
Rice University. (2023). Utah FORGE Project 3-2417: Simulations for Distributed Acoustic Sensing Strain Signatures as an Indicator of Fracture Connectivity [data set]. Retrieved from https://dx.doi.org/10.15121/2369582.
Ward-Baranyay, Megan, Ajo-Franklin, Jonathan, and Ghassemi, Ahmad. Utah FORGE Project 3-2417: Simulations for Distributed Acoustic Sensing Strain Signatures as an Indicator of Fracture Connectivity. United States: N.p., 01 Jan, 2023. Web. doi: 10.15121/2369582.
Ward-Baranyay, Megan, Ajo-Franklin, Jonathan, & Ghassemi, Ahmad. Utah FORGE Project 3-2417: Simulations for Distributed Acoustic Sensing Strain Signatures as an Indicator of Fracture Connectivity. United States. https://dx.doi.org/10.15121/2369582
Ward-Baranyay, Megan, Ajo-Franklin, Jonathan, and Ghassemi, Ahmad. 2023. "Utah FORGE Project 3-2417: Simulations for Distributed Acoustic Sensing Strain Signatures as an Indicator of Fracture Connectivity". United States. https://dx.doi.org/10.15121/2369582. https://gdr.openei.org/submissions/1582.
@div{oedi_6051, title = {Utah FORGE Project 3-2417: Simulations for Distributed Acoustic Sensing Strain Signatures as an Indicator of Fracture Connectivity}, author = {Ward-Baranyay, Megan, Ajo-Franklin, Jonathan, and Ghassemi, Ahmad.}, abstractNote = {This dataset encompasses simulations of strain signatures from both hydraulically connected and "near-miss" fractures in enhanced geothermal systems (EGS). The files and results are presented from the perspective of digital acoustic sensing's (DAS) potential to differentiate the two fracture types. This dataset was acquired by the FOGMORE R&D project (Fiber Optic Geophysical MOnitoring of Reservoir Evolution), under Utah FORGE R&D Project 3-2417. Included are simulation and results via MatLab and COMSOL files, as well as a thesis and paper summarizing the results.
Some stimulated fractures may be incomplete, approaching but not intersecting the production well. These "near-miss" fractures can be addressed in future stimulation stages or re-stimulated to complete the connection. We propose the use of fiber optic distributed acoustic sensing (DAS) as a method by which near-miss stimulated fractures may be identified and distinguished from hydraulically connected fractures. The low-frequency sub-nanostrain signatures of both complete and near-miss fractures in DAS data are simulated in this study using a hydrogeomechanical discrete fracture network model. The spatial distribution of strain was found to be an accurate indicator. However, this indicator must be evaluated in the context of DAS gauge length and spatial sampling. These simulations are a precursor to tests conducted at FORGE in 2023.}, doi = {10.15121/2369582}, url = {https://gdr.openei.org/submissions/1582}, journal = {}, number = , volume = , place = {United States}, year = {2023}, month = {01}}
https://dx.doi.org/10.15121/2369582
Details
Data from Jan 1, 2023
Last updated Jun 3, 2024
Submitted May 10, 2024
Organization
Rice University
Contact
Matthew W Becker
562.985.8983
Authors
Original Source
https://gdr.openei.org/submissions/1582Research Areas
Keywords
geothermal, energy, FORGE, Utah FORGE, EGS, Milford, Utah, COMSOL, DFN, MatLab, simulation, near-miss fracture, DAS, distributed acoustic sensing, modeling, strain, FOGMORE, geophysics, hydrogeomechanics, sub-nanostrain, code, stimulationDOE Project Details
Project Name Utah FORGE
Project Lead Lauren Boyd
Project Number EE0007080