Subsurface Energy Storage

Sandia’s program in subsurface energy storage connects our expertise in underground energy storage with researchers and developers in commercial, industrial, and academic settings. Together, we are building national expertise in wellbore integrity for oil, gas, and carbon storage, as well as geologic hydrogen and hydrogen storage.

Our combined experts, facilities, drilling technology, and cement seal research make Sandia a leading research and development institution for the subsurface storage of hydrogen, helium, compressed air, natural gas, and oil products—including the identification and repair of existing well bores.

  • We conduct research to understand the current state of both legacy wells and currently operating wells.  This includes educating on current integrity issues, understanding the mechanisms for loss of integrity, and working towards learning how to protect those assets, both from an engineering aspect and a regulatory aspect.
  • We also apply our knowledge and understanding of underground storage to other industries developing new energy storage methods.

Sandia has been the geotechnical adviser for the Strategic Petroleum Reserve (SPR), the world’s largest supply of emergency crude oil, for 40 years. We are responsible for characterizing the site, which includes cavern and well development, geomechanical analysis, ensuring the integrity of caverns and wells, subsidence, and monitoring. Sandia’s many subsurface capabilities enable us to support the major changes that are taking place at SPR in terms of life extension programs and the possibility of more dynamic fill/withdrawal operations.

Sandia’s expertise, coupled with drilling technology and cement seal research, makes Sandia capable of leadership roles in subsurface storage for hydrogen, helium, compressed air, natural gas, and oil products, including the identification and repair of existing well bores.

Sandia’s team completes subsurface rock testing
Sandia’s team completes subsurface rock testing
One of four SPR Salt Dome sites
One of four SPR Salt Dome sites
Typical wellhead configuration for the SPR caverns
Typical wellhead configuration for the SPR caverns

Projects

Aliso Canyon/California Geologic Energy Management Division (CalGEM)

Sandia was asked to review the kill well procedure during the Aliso Canyon natural gas storage well leak. In response to the Aliso Canyon gas leak, Sandia was involved in helping to develop new state regulations, using science to ensure that well integrity is monitored. We are also reviewing the Aliso Canyon Root Cause Analysis as Subject Matter Experts and analyzing workplans for geologic, seismologic, and geomechanical hazards at the site.

 Commercial Cavern Analysis

Sandia teams with commercial partners to offer operational decision-quality modeling and analysis for cavern stability and dome-wide impacts of new cavern emplacement.

 U.S. Strategic Petroleum Reserve (SPR)

Sandia is responsible for establishing testing, certification, and monitoring procedures for, and predicting the long-term behavior of the SPR.

Sandia’s work for the SPR consists primarily of the following technical activities:

  • Underground Storage of Crude Oil
  • Site Planning of Storage Facilities
  •  Site Characterization Studies
  •  Brine Disposal
  •  Cavern Integrity Monitoring and Testing
  •  Well Integrity Monitoring and Testing
  •  Subsidence Modeling
  •  Microseismic Analysis & Other Monitoring Technologies
  •  Oil and Brine Chemistry
  •  Full Cavern/Well Design and Development
  •  Cavern Operational Analyses
  •  Robust Geomechanical Modeling

Investments

Capabilities
  • Extensive modeling capabilities
  • Field scale testing and employment: Development and deployment of a high-temperature and high-pressure chemical sensing downhole tool. Used for in-situ fracture connectivity mapping, high-temperature electrochemistry, and real-time pH measurements
  • Large rock mechanics testing laboratory: Capable of running triaxial stress and strain tests on rock and other materials, along with long-term temperature-controlled creep tests
  • Subsurface characterization in three-dimensions and in time
  • Subsurface sensors: Design and deployment of sensors and subsurface wireline tools
 Unique Sandia-Created Tools
  • CAVEMAN
    • Monitoring code that offers real-time cavern leak monitoring based on detection of other-than-expected wellhead pressures
  • SIERRA SOLID MECHANICS ADAGIO CODE
    • Performs mechanical modeling calculations on Sandia’s High Performance Computing systems
  • Kayenta
    • A computational framework for generalized plasticity models
  • PFLOTRAN
    • Aims to solve a system of generally nonlinear partial differential equations describing multiphase, multicomponent, and multiscale flow and transport in porous materials with multiphysical features
  • SANSMIC
    • A salt solution mining code used to aid in the development of salt caverns
  • SIERRA/ADAGIO
    • Sandia-developed 3D solid mechanics code used as a solver for salt mechanical behavior; ADAGIO uses the SIERRA Framework, which allows for coupling with other SIERRA mechanics codes
CAVEMAN test results
CAVEMAN test results
High-performance computational modeling
High-performance computational modeling
SANSMIC test results
SANSMIC test results

Future

In addition to providing technology support to the SPR, Sandia works with industry and academic partners in the planning, development, and operation of underground salt caverns for the storage of liquid and gaseous hydrocarbons. Our focus is onsite planning, geological investigations, cavern and subsurface mechanics, wellbore integrity, oil chemistry, operational analyses and salt leaching analyses while also providing project support in materials, multi-phase fluid flow, engineering, turbulence/shock analysis and other areas of expertise.

We will continue to support the SPR, our partners, and industry by:

  • Completing direct subsurface measurements through precise micro-drilling
  • Advancing downhole sensing for wellbore integrity
  • Providing wellbore risk assessment expertise
  • Advancing extensive geomechanical modeling capabilities for industry
  • Conducting spatial and geostatistical analyses
  • Conducting energy system resiliency analyses focusing on security and disaster recovery
  • Engineering capabilities for process plant simulation and pressure-volume-temperature modeling of gases and liquids, including underground storage
  • Monitoring and repair of damaged cement-geomaterial interfaces in high pressure high temperature repository and borehole scenarios (Sandia, University of New Mexico, and University of Texas at Austin partnership)
  • Working with federal regulators, namely the Pipeline and Hazardous Materials Safety Administration (PHMSA), on reliability of subsurface safety valves in underground natural gas storage and regarding tubing and packers lifecycle for unattended ground sensor applications (Sandia and Battelle Memorial Institute partnership)
  • Advancing detection of wellbore failure for safe and secure utilization of subsurface infrastructure (Sandia, University of New Mexico, Battelle Memorial Institute, and Chevron partnership)

Publications

  • Searfus, O.F., Marleau, P.A., Jovanovic, I., & Jovanovic, I. (2024). Response of a high-pressure 4He scintillation detector to nuclear recoils up to 9 MeV. Nuclear Instruments and Methods in Physics Research. Section A, Accelerators, Spectrometers, Detectors and Associated Equipment, 1066(2024). https://doi.org/10.1016/j.nima.2024.169608 Publication ID: 124948
  • Micheli, L., Muller, M., Theristis, M., Smestad, G.P., Almonacid, F., Fernandez, E.F., & Fernandez, E.F. (2024). Quantifying the impact of inverter clipping on photovoltaic performance and soiling losses. Renewable Energy, 225. https://doi.org/10.1016/j.renene.2024.120317 Publication ID: 124252
  • Mishra, U., Tao, F., Houlton, B.Z., Huang, Y., Wang, Y.P., Manzoni, S., Ahrens, B., Jiang, L., Huang, X., Luo, Y., & Luo, Y. (2024). Convergence in simulating global soil organic carbon by structurally different models after data assimilation. Global Change Biology, 30(5). https://doi.org/10.1111/gcb.17297 Publication ID: 124612
  • Mishra, U., Shi, Z., Hoffman, F.M., Xu, M., Allison, S.D., Zhou, J., Randerson, J.T., & Randerson, J.T. (2024). Global-Scale Convergence Obscures Inconsistencies in Soil Carbon Change Predicted by Earth System Models. AGU Advances, 5(2). https://doi.org/10.1029/2023av001068 Publication ID: 124296
  • Hwang, J., Karathanassis, I.K., Koukouvinis, P., Nguyen, T., Tagliante, F., Pickett, L.M., Sforzo, B.A., Powell, C.F., & Powell, C.F. (2024). Spray process of multi-component gasoline surrogate fuel under ECN Spray G conditions. International Journal of Multiphase Flow, 174. https://doi.org/10.1016/j.ijmultiphaseflow.2024.104753 Publication ID: 122740
  • Bachand, G.D., Rempe, S.B., Manginell, M., Coker, E.N., Chiang, R., Sharma, A., Nardi, I., & Nardi, I. (2024). Engineered living materials for capture, conversion, and recycling technologies. https://doi.org/10.2172/2325002 Publication ID: 124272
  • Wang, J., Clayton, D., Dewji, S.A., & Dewji, S.A. (2024). Comparison of atmospheric radionuclide dispersion models for a risk-informed consequence-driven advanced reactor licensing framework. Journal of Environmental Radioactivity, 273(1). https://doi.org/10.1016/j.jenvrad.2024.107379 Publication ID: 122908
  • Zhou, W., Zhang, L., Sheshukov, A., Wang, J., Zhu, M., Sargsyan, K., Xu, D., Liu, D., Zhang, T., Mazepa, V., Sokolov, A., Valdayskikh, V., Ivanov, V., & Ivanov, V. (2024). Ground Heat Flux Reconstruction Using Bayesian Uncertainty Quantification Machinery and Surrogate Modeling. Earth and Space Science, 11(3). https://doi.org/10.1029/2023ea003435 Publication ID: 124240
  • Anderson, E.M., Motes, A.G., Sproul, E.G., Mertz, B., Paquette, J., & Paquette, J. (2024). Investigation of an Intermittent Binary Control Strategy for Distributed Aerodynamic Control Devices for Load Alleviation in Wind Turbine Blades. https://www.osti.gov/biblio/2429999 Publication ID: 125152
  • Lopez-Pintor, D., Abboud, R., MacDonald, J., Lee, S., & Lee, S. (2024). Effect of Cyclo-Pentane Impurities on the Autoignition Reactivity and Properties of a Gasoline Surrogate Fuel. SAE Technical Papers, 1. https://doi.org/10.4271/2024-01-5021 Publication ID: 122808
  • Rencheck, M.L., Libby, C., Montgomery, A., Stein, J.S., & Stein, J.S. (2024). Managing potential environmental and human health risks of lead halide perovskite photovoltaic modules. Solar Energy, 269(112337). https://doi.org/10.1016/j.solener.2024.112337 Publication ID: 122604
  • Micheli, L., Muller, M., Theristis, M., Smestad, G., Almonacid, F., Fernandez, E., & Fernandez, E. (2024). Inverter clipping and its masking effect on PV soiling: truth or myth? [Conference Poster]. https://doi.org/10.2172/2335911 Publication ID: 124432
  • Wheeler, L.B., Zeitler, T., Brunell, S.B., Lien, J.M., Shand, L., Wagman, B.M., Roesler, E.L., Martinez, C., Potter, K.M., & Potter, K.M. (2023). Performance assessment for climate intervention (PACI): preliminary application to a stratospheric aerosol injection scenario. Frontiers in Environmental Science, 11(1205515). https://doi.org/10.3389/fenvs.2023.1205515 Publication ID: 122544
  • Jaryenneh, J., Schoeniger, J.S., Mageeney, C.M., & Mageeney, C.M. (2023). Genome sequence and characterization of a novel Pseudomonas putida phage, MiCath. Scientific Reports, 13(1). https://doi.org/10.1038/s41598-023-48634-z Publication ID: 122516
  • Trott, W.M. (2023). Studies of Laser-Driven Flyer Acceleration Using Optical Fiber Coupling [Book Chapter] [Conference]. Shock Compression of Condensed Matter–1991. https://doi.org/10.1016/b978-0-444-89732-9.50190-4 Publication ID: 133088
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Contact

Don Conley

(505) 845-3555

dconley@sandia.gov