Abstract
Submerged oil, oil in the water column (neither at the surface nor on the bottom), was found in the form of oil droplet layers in the mid depths between 900–1300 m in the Gulf of Mexico during and following the Deepwater Horizon oil spill. The subsurface peeling layers of submerged oil droplets were released from the well blowout plume and moved along constant density layers (also known as isopycnals) in the ocean. The submerged oil layers were a challenge to locate during the oil spill response. To better understand and find submerged oil layers, we review the mechanisms of submerged oil formation, along with detection methods and modeling techniques. The principle formation mechanisms under stratified and cross-current conditions and the concepts for determining the depths of the submerged oil layers are reviewed. Real-time in situ detection methods and various sensors were used to reveal submerged oil characteristics, e.g., colored dissolved organic matter and dissolved oxygen levels. Models are used to locate and to predict the trajectories and concentrations of submerged oil. These include deterministic models based on hydrodynamical theory, and probabilistic models exploiting statistical theory. The theoretical foundations, model inputs and the applicability of these models during the Deepwater Horizon oil spill are reviewed, including the pros and cons of these two types of models. Deterministic models provide a comprehensive prediction on the concentrations of the submerged oil and may be calibrated using the field data. Probabilistic models utilize the field observations but only provide the relative concentrations of the submerged oil and potential future locations. We find that the combination of a probabilistic integration of real-time detection with trajectory model output appears to be a promising approach to support emergency response efforts in locating and tracking submerged oil in the field.
Highlights
In the Deepwater Horizon (DWH) oil spill, oil droplets were found at a depth of 900–1300 m that persisted for more than six months [1]
Before September, the oil response during the DWH spill mainly focused on stopping the leaking of the well and cleaning the surface and shoreline oil
Devices such as AUV Sentry needed to search a broad area to find the subsurface oil [75]. Another possible reason is after Sep 1, many academic vessels on scene participated in the daily submerged oil monitoring mission, which maximized vessel time and sample location [26]
Summary
In the Deepwater Horizon (DWH) oil spill, oil droplets were found at a depth of 900–1300 m that persisted for more than six months [1]. To find the submerged oil during response, proper estimates of the submerged oil distributions and trajectories are needed. In order to get an accurate estimate, a good understanding on the submerged oil formation mechanisms is desired, together with proper detection methods and modeling techniques [4]. Studies on the formation of submerged oil [5,6,7,8,9] help estimate the depths of the intrusion layers and provide guidance on where to find the submerged oil. Modeling techniques can be applied to estimate the entire distributions and trajectories of submerged oil [12,14]. The model results can be used by oil response teams to determine sampling locations, potential trajectories of the subsurface oil layer, and whether or not to continue to carry out or continue subsurface dispersant injection (SSDI) [10]. The collected field data can be used for model calibrations and to improve model prediction accuracy
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