Marine Science Faculty Publications
Far-Field Modeling of a Deep-Sea Blowout: Sensitivity Studies of Initial Conditions, Biodegradation, Sedimentation, and Subsurface Dispersant Injection on Surface Slicks and Oil Plume Concentrations
Document Type
Book Chapter
Publication Date
6-2019
Keywords
Deep-sea blowout, Subsea oil spill, Oil transport modeling, Oil fate modeling, Biogeophysical oil modeling, Connectivity Modeling System, Subsurface dispersant injection (SSDI) effects
Digital Object Identifier (DOI)
https://doi.org/10.1007/978-3-030-11605-7_11
Abstract
Modeling of large-scale oil transport and fate resulting from deep-sea oil spills is highly complex due to a number of bio-chemo-geophysical interactions, which are often empirically based. Predicting mass-conserved total petroleum hydrocarbon concentrations is thus still a challenge for most oil spill models. In addition, dynamic quantification and visualization of spilled oil concentrations are necessary both for first response and basin-wide impact studies. This chapter presents a new implementation of the Connectivity Modeling System (CMS) oil application that tracks individual multi-fraction oil droplets and estimates oil concentrations and oil mass in a 3D space grid. We used the Deepwater Horizon (DWH) blowout as a case study and performed a sensitivity analysis of several modeling key factors, such as biodegradation, sedimentation, and alternative initial conditions, including droplet size distribution (DSD) corresponding to an untreated and treated live oil from subsurface dispersant injection (SSDI) predicted experimentally under high pressure and by the VDROP-J jet-droplet formation model. This quantitative analysis enabled the reconstruction of a time evolving three-dimensional (3D) oil plume in the ocean interior, the rising and spreading of oil on the ocean surface, and the effect of SSDI in shifting the oil to deeper waters while conserving the mass balance. Our modeling framework and analyses are thus important technical advances for understanding and mitigating deep-sea blowouts.
Was this content written or created while at USF?
Yes
Citation / Publisher Attribution
Far-Field Modeling of a Deep-Sea Blowout: Sensitivity Studies of Initial Conditions, Biodegradation, Sedimentation, and Subsurface Dispersant Injection on Surface Slicks and Oil Plume Concentrations, in S. A. Murawski, C. H. Ainsworth, S. Gilbert, D. J. Hollander, C. B. Paris, M. Schlüter & D. L. Wetzel (Eds.), Deep Oil Spills Facts, Fate, and Effects, Springer, p. 170-192
Scholar Commons Citation
Perlin, Natalie; Paris, Claire B.; Berenshtein, Igal; Vaz, Ana C.; Faillettaz, Robin; Aman, Zachary M.; Schwing, Patrick; Romero, Isabel C.; Schlüter, Michael; Liese, Andreas; Noirungsee, Nuttapol; and Hackbusch, Steffen, "Far-Field Modeling of a Deep-Sea Blowout: Sensitivity Studies of Initial Conditions, Biodegradation, Sedimentation, and Subsurface Dispersant Injection on Surface Slicks and Oil Plume Concentrations" (2019). Marine Science Faculty Publications. 460.
https://digitalcommons.usf.edu/msc_facpub/460
Comments
Data used in this book chapter are available for download.
Three-dimensional daily oil concentrations and oil mass estimates in the Gulf of Mexico from the modeling of the Deepwater Horizon 2010 oil spill using a Connectivity Modeling System