Utah FORGE 2439: A Multi-Component Approach to Characterizing In-Situ Stress
Core-based in-situ stress estimation, Triaxial Ultrasonic Velocity (labTUV) data, and Deformation Rate Analysis (DRA) data for Utah FORGE well 16A(78)-32 using triaxial ultrasonic velocity and deformation rate analysis. Report documenting a multi-component approach to characterizing in-situ stress at the U.S. DOE FORGE EGS site: laboratory, modeling and field measurement.
Core-based methods for in-situ stress estimation were applied using samples from 5 intervals within the Utah FORGE 16A(78)-32 well. At three of these locations, Triaxial Ultrasonic Velocity (labTUV) tests were performed, resulting in experimentally-determined relationships between wave velocities and stresses. Non-monotonic increase in the velocity-stress relationships are inferred provide evidence of stress history and are therefore used to estimate in-situ stress magnitudes. Additionally, Deformation Rate Analysis (DRA) tests were run on core plugs from various orientations at each of the 5 sampling locations. These, too, provide evidence of stress history based on stress-strain behavior. A novel Weight of Evidence (WoE) method was developed as a means of synthesizing in-situ stress evidence from these two types of tests. Results indicate the minimum horizontal stress gradient ranges from 0.58 psi/ft to 0.69 psi/ft, with 4 of the 5 values between 0.66 psi/ft and 0.69 psi/ft. The vertical stress gradient ranges from 1.05 psi/ft to 1.12 psi/ft, with 4 of the 5 zones given results between 1.09 psi/ft and 1.12 psi/ft. The maximum horizontal stress gradient ranges from 0.98 psi/ft to 1.34 psi/ft, with 4 of the 5 zones falling between 0.98 psi/ft and 1.24 psi/ft. The stress regime thus appears to be on the edge between normal faulting and strike-slip faulting, potentially flipping back and forth between the two regimes due to variability of rock properties, structures such as faults, and/or thermal anomalies.
Citation Formats
TY - DATA
AB - Core-based in-situ stress estimation, Triaxial Ultrasonic Velocity (labTUV) data, and Deformation Rate Analysis (DRA) data for Utah FORGE well 16A(78)-32 using triaxial ultrasonic velocity and deformation rate analysis. Report documenting a multi-component approach to characterizing in-situ stress at the U.S. DOE FORGE EGS site: laboratory, modeling and field measurement.
Core-based methods for in-situ stress estimation were applied using samples from 5 intervals within the Utah FORGE 16A(78)-32 well. At three of these locations, Triaxial Ultrasonic Velocity (labTUV) tests were performed, resulting in experimentally-determined relationships between wave velocities and stresses. Non-monotonic increase in the velocity-stress relationships are inferred provide evidence of stress history and are therefore used to estimate in-situ stress magnitudes. Additionally, Deformation Rate Analysis (DRA) tests were run on core plugs from various orientations at each of the 5 sampling locations. These, too, provide evidence of stress history based on stress-strain behavior. A novel Weight of Evidence (WoE) method was developed as a means of synthesizing in-situ stress evidence from these two types of tests. Results indicate the minimum horizontal stress gradient ranges from 0.58 psi/ft to 0.69 psi/ft, with 4 of the 5 values between 0.66 psi/ft and 0.69 psi/ft. The vertical stress gradient ranges from 1.05 psi/ft to 1.12 psi/ft, with 4 of the 5 zones given results between 1.09 psi/ft and 1.12 psi/ft. The maximum horizontal stress gradient ranges from 0.98 psi/ft to 1.34 psi/ft, with 4 of the 5 zones falling between 0.98 psi/ft and 1.24 psi/ft. The stress regime thus appears to be on the edge between normal faulting and strike-slip faulting, potentially flipping back and forth between the two regimes due to variability of rock properties, structures such as faults, and/or thermal anomalies.
AU - Bunger, Andrew
A2 - Higgins, Joshua
A3 - Huang, Yao
A4 - Kelley, Mark
DB - Open Energy Data Initiative (OEDI)
DP - Open EI | National Laboratory of the Rockies
DO - 10.15121/1923003
KW - geothermal
KW - energy
KW - Utah FORGE
KW - In-Situ Stress
KW - Laboratory
KW - Modeling
KW - Field Measurement
KW - TUV
KW - Triaxial Ultrasonic Velocity
KW - Deformation Rate Analysis
KW - DRA
KW - Weight of Evidence
KW - WoE
KW - EGS
KW - Stress Test
KW - Characterization
KW - Well Data
KW - geophysics
KW - FORGE
KW - 16A78-32
LA - English
DA - 2022/12/13
PY - 2022
PB - Battelle Memorial Institute
T1 - Utah FORGE 2439: A Multi-Component Approach to Characterizing In-Situ Stress
UR - https://doi.org/10.15121/1923003
ER -
Bunger, Andrew, et al. Utah FORGE 2439: A Multi-Component Approach to Characterizing In-Situ Stress. Battelle Memorial Institute, 13 December, 2022, GDR. https://doi.org/10.15121/1923003.
Bunger, A., Higgins, J., Huang, Y., & Kelley, M. (2022). Utah FORGE 2439: A Multi-Component Approach to Characterizing In-Situ Stress. [Data set]. GDR. Battelle Memorial Institute. https://doi.org/10.15121/1923003
Bunger, Andrew, Joshua Higgins, Yao Huang, and Mark Kelley. Utah FORGE 2439: A Multi-Component Approach to Characterizing In-Situ Stress. Battelle Memorial Institute, December, 13, 2022. Distributed by GDR. https://doi.org/10.15121/1923003
@misc{OEDI_Dataset_8504,
title = {Utah FORGE 2439: A Multi-Component Approach to Characterizing In-Situ Stress},
author = {Bunger, Andrew and Higgins, Joshua and Huang, Yao and Kelley, Mark},
abstractNote = {Core-based in-situ stress estimation, Triaxial Ultrasonic Velocity (labTUV) data, and Deformation Rate Analysis (DRA) data for Utah FORGE well 16A(78)-32 using triaxial ultrasonic velocity and deformation rate analysis. Report documenting a multi-component approach to characterizing in-situ stress at the U.S. DOE FORGE EGS site: laboratory, modeling and field measurement.
Core-based methods for in-situ stress estimation were applied using samples from 5 intervals within the Utah FORGE 16A(78)-32 well. At three of these locations, Triaxial Ultrasonic Velocity (labTUV) tests were performed, resulting in experimentally-determined relationships between wave velocities and stresses. Non-monotonic increase in the velocity-stress relationships are inferred provide evidence of stress history and are therefore used to estimate in-situ stress magnitudes. Additionally, Deformation Rate Analysis (DRA) tests were run on core plugs from various orientations at each of the 5 sampling locations. These, too, provide evidence of stress history based on stress-strain behavior. A novel Weight of Evidence (WoE) method was developed as a means of synthesizing in-situ stress evidence from these two types of tests. Results indicate the minimum horizontal stress gradient ranges from 0.58 psi/ft to 0.69 psi/ft, with 4 of the 5 values between 0.66 psi/ft and 0.69 psi/ft. The vertical stress gradient ranges from 1.05 psi/ft to 1.12 psi/ft, with 4 of the 5 zones given results between 1.09 psi/ft and 1.12 psi/ft. The maximum horizontal stress gradient ranges from 0.98 psi/ft to 1.34 psi/ft, with 4 of the 5 zones falling between 0.98 psi/ft and 1.24 psi/ft. The stress regime thus appears to be on the edge between normal faulting and strike-slip faulting, potentially flipping back and forth between the two regimes due to variability of rock properties, structures such as faults, and/or thermal anomalies.},
url = {https://gdr.openei.org/submissions/1438},
year = {2022},
howpublished = {GDR, Battelle Memorial Institute, https://doi.org/10.15121/1923003},
note = {Accessed: 2026-07-07},
doi = {10.15121/1923003}
}
https://dx.doi.org/10.15121/1923003
Details
Data from Dec 13, 2022
Last updated Feb 18, 2025
Submitted Dec 14, 2022
Organization
Battelle Memorial Institute
Contact
Mark Kelley
614.424.3704
Authors
Original Source
https://gdr.openei.org/submissions/1438Research Areas
Keywords
geothermal, energy, Utah FORGE, In-Situ Stress, Laboratory, Modeling, Field Measurement, TUV, Triaxial Ultrasonic Velocity, Deformation Rate Analysis, DRA, Weight of Evidence, WoE, EGS, Stress Test, Characterization, Well Data, geophysics, FORGE, 16A78-32DOE Project Details
Project Name Utah FORGE
Project Lead Lauren Boyd
Project Number EE0007080

