Reservoir Stimulation Optimization with Operational Monitoring for Creation of EGS
EGS field projects have not sustained production at rates greater than 1/2 of what is needed for economic viability. The primary limitation that makes commercial EGS infeasible is our current inability to cost-effectively create high-permeability reservoirs from impermeable, igneous rock within the 3,000-10,000 ft depth range. Our goal is to develop a novel fracturing fluid technology that maximizes reservoir permeability while reducing stimulation cost and environmental impact. Laboratory equipment development to advance laboratory characterization/monitoring is also a priority of this project to study and optimize the physicochemical properties of these fracturing fluids in a range of reservoir conditions. Barrier G is the primarily intended GTO barrier to be addressed as well as support addressing barriers D, E and I.
Citation Formats
Pacific Northwest National Laboratory. (2014). Reservoir Stimulation Optimization with Operational Monitoring for Creation of EGS [data set]. Retrieved from https://dx.doi.org/10.15121/1261928.
A., Carlos. Reservoir Stimulation Optimization with Operational Monitoring for Creation of EGS. United States: N.p., 15 Sep, 2014. Web. doi: 10.15121/1261928.
A., Carlos. Reservoir Stimulation Optimization with Operational Monitoring for Creation of EGS. United States. https://dx.doi.org/10.15121/1261928
A., Carlos. 2014. "Reservoir Stimulation Optimization with Operational Monitoring for Creation of EGS". United States. https://dx.doi.org/10.15121/1261928. https://gdr.openei.org/submissions/455.
@div{oedi_3271, title = {Reservoir Stimulation Optimization with Operational Monitoring for Creation of EGS}, author = {A., Carlos.}, abstractNote = {EGS field projects have not sustained production at rates greater than 1/2 of what is needed for economic viability. The primary limitation that makes commercial EGS infeasible is our current inability to cost-effectively create high-permeability reservoirs from impermeable, igneous rock within the 3,000-10,000 ft depth range. Our goal is to develop a novel fracturing fluid technology that maximizes reservoir permeability while reducing stimulation cost and environmental impact. Laboratory equipment development to advance laboratory characterization/monitoring is also a priority of this project to study and optimize the physicochemical properties of these fracturing fluids in a range of reservoir conditions. Barrier G is the primarily intended GTO barrier to be addressed as well as support addressing barriers D, E and I.
}, doi = {10.15121/1261928}, url = {https://gdr.openei.org/submissions/455}, journal = {}, number = , volume = , place = {United States}, year = {2014}, month = {09}}
https://dx.doi.org/10.15121/1261928
Details
Data from Sep 15, 2014
Last updated Jun 27, 2017
Submitted Nov 4, 2014
Organization
Pacific Northwest National Laboratory
Contact
Carlos A. Fernandez
509.371.7020
Authors
Original Source
https://gdr.openei.org/submissions/455Research Areas
Keywords
geothermal, stress, volume expansion, permeability, fracturing, rheoreversible fluids, XMT, acoustic emission, laboratory scale, EGS, igneous rock, acoustic signature, fracture response, x-ray microtomographyDOE Project Details
Project Lead Dan King
Project Number FY14 AOP 1.3.2.2
