Skip to main content
OSTI.GOVU.S. Department of Energy Office of Scientific and Technical Information
U.S. Department of Energy
Office of Scientific and Technical Information
 

Processed Lab Data for Neural Network-Based Shear Stress Level Prediction

Dataset ·
DOI:https://doi.org/10.15121/1787545· OSTI ID:1787545
 [1]
  1. Pennsylvania State University
+ Show Author Affiliations

Machine learning can be used to predict fault properties such as shear stress, friction, and time to failure using continuous records of fault zone acoustic emissions. The files are extracted features and labels from lab data (experiment p4679). The features are extracted with a non-overlapping window from the original acoustic data. The first column is the time of the window. The second and third columns are the mean and the variance of the acoustic data in this window, respectively. The 4th-11th column is the the power spectrum density ranging from low to high frequency. And the last column is the corresponding label (shear stress level). The name of the file means which driving velocity the sequence is generated from. Data were generated from laboratory friction experiments conducted with a biaxial shear apparatus. Experiments were conducted in the double direct shear configuration in which two fault zones are sheared between three rigid forcing blocks. Our samples consisted of two 5-mm-thick layers of simulated fault gouge with a nominal contact area of 10 by 10 cm^2. Gouge material consisted of soda-lime glass beads with initial particle size between 105 and 149 micrometers. Prior to shearing, we impose a constant fault normal stress of 2 MPa using a servo-controlled load-feedback mechanism and allow the sample to compact. Once the sample has reached a constant layer thickness, the central block is driven down at constant rate of 10 micrometers per second. In tandem, we collect an AE signal continuously at 4 MHz from a piezoceramic sensor embedded in a steel forcing block about 22 mm from the gouge layer The data from this experiment can be used with the deep learning algorithm to train it for future fault property prediction.

Research Organization:
DOE Geothermal Data Repository; Pennsylvania State University
Sponsoring Organization:
USDOE Office of Energy Efficiency and Renewable Energy (EERE), Renewable Power Office. Geothermal Technologies Program (EE-4G)
Contributing Organization:
Pennsylvania State University
DOE Contract Number:
EE0008763
OSTI ID:
1787545
Report Number(s):
1312
Availability:
GDRHelp@ee.doe.gov
Country of Publication:
United States
Language:
English

Similar Records

The Effect of Normal Stress Oscillations on Fault Slip Behavior Near the Stability Transition From Stable to Unstable Motion
Journal Article · Mon Feb 12 23:00:00 EST 2024 · Journal of Geophysical Research. Solid Earth · OSTI ID:2538738

Related Subjects

15 GEOTHERMAL ENERGY
Biaxial Shear Experiment
MATLAB
acoustic emissions
acoustics
ai
artificial intelligence
biaxial shear apparatus
code
deep learning
energy
experiment
experimental data
fault
fault properties
friction
geophysics
geothermal
lab data
machine learning
microseismicity
processed data
seismic
seismic forcasting
seismic prediction
shear stress
time to failure