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Cody Massion
Research Lab ManagerOklahoma State University
cody.massion@okstate.edu
Mitigating Risks to Hydrocarbon Release through Integrative Advanced Materials for Wellbore Plugging and Remediation
Leaky wellbores with inadequate well plugging materials can allow for the release of hydrocarbons into the ocean at low rates for decades, resulting in cumulative damage to surrounding areas. The goal of this project is to advance capabilities for the prevention and remediation of wellbore leakage in offshore hydrocarbon-producing wells. The project will develop and test new materials to improve or replace current materials used in the plugging and abandonment of wells and develop new methods for placing such materials.
National Academies of Science, Engineering, Medicine: Gulf Research Program
MITIGATING RISKS TO HYDROCARBON RELEASE THROUGH INTEGRATIVE ADVANCED MATERIALS FOR WELLBORE PLUGGING AND REMEDIATION_Oklahoma State University Dataset
Identified On: Nov 30 2022 19:11 UTC
UDI: S3.x932.000:0001
File Size: 196.58 GB
Achang, M., & Radonjic, M. (2021). Adding olivine micro particles to Portland cement based wellbore cement slurry as a sacrificial material: A quest for the solution in mitigating corrosion of wellbore cement. Cement and Concrete Composites, 121, 104078. https://doi.org/10.1016/j.cemconcomp.2021.104078
Katende, A., Lu, Y., Bunger, A., & Radonjic, M. (2020). Experimental quantification of the effect of oil based drilling fluid contamination on properties of wellbore cement. Journal of Natural Gas Science and Engineering, 79, 103328. https://doi.org/10.1016/j.jngse.2020.103328
Massion, C., Lu, Y., Crandall, D., Bunger, A., & Radonjic, M. (2022). Graphene nanoplatelets reinforced cement as a solution to leaky wellbores reinforcing weak points in hydrated Portland cement with graphene nanoparticles improves mechanical and chemical durability of wellbore cements. Cement and Concrete Composites, 133, 104726. https://doi.org/10.1016/j.cemconcomp.2022.104726
Massion, C., Vissa, V. S. K., Lu, Y., Crandall, D., Bunger, A., & Radonjic, M. (2022). Geomimicry-Inspired Micro-Nano Concrete as Subsurface Hydraulic Barrier Materials: Learning from Shale Rocks as Best Geological Seals. In REWAS 2022: Energy Technologies and CO2 Management (Volume II) (pp. 129–138). Springer International Publishing. https://doi.org/10.1007/978-3-030-92559-8_13