Study Finds “Business as Usual” for Hypoxic Zone Following Deepwater Horizon
Researchers compared long-term data from low-oxygen (hypoxia) studies to determine if the Deepwater Horizon incident affected the Gulf of Mexico seasonal hypoxic area.
Researchers compared long-term data from low-oxygen (hypoxia) studies to determine if the Deepwater Horizon incident affected the Gulf of Mexico seasonal hypoxic area.
Researchers conducted incubation experiments and examined the roles of temperature, nutrients, and initial bacterial community on oil biodegradation. Higher and lower temperatures yielded distinctly different bacterial community compositions, indicating that temperature is a key influencer of bacteria that respond when oil is present.
Scientists detailed how they designed and tested an ocean drifter that tracks and measures shallow-depth (0.60 m) surface currents. The final version, called the CARTHE drifter, is made from a polymer produced by bacteria fed with corn sugar.
Researchers conducted 48-hour toxicity experiments on deep ocean crustaceans (200 – 1000 m depth) to determine the impact threshold levels for one polycyclic aromatic hydrocarbon (PAH, 1-methylnaphthalene) under various environmental conditions.
Researchers identified small- to hurricane-scale resuspension events using time-series data of sinking organic material near the Deepwater Horizon site.
Researchers conducted a first-of-its-kind measurement of the vertical dynamics of water motion near the ocean’s surface in the northern Gulf of Mexico.
Researchers analyzed the resource use of Seaside Sparrows residing in salt marshes impacted by large-scale disturbances like Deepwater Horizon and Hurricane Isaac to understand the effects on these indicators of ecological change.
Researchers conducted laboratory wave tank experiments to investigate how plunging breaking waves affect the concentration of particulate and gaseous emissions from oil slicks.
Researchers assessed several years of sediment trap collections near the Deepwater Horizon site, an active natural seep site, and a reference site to understand transport pathways and drivers of sinking particles in deepwater environments (1400 m depth).
Researchers conducted exposure experiments with mahi-mahi embryos using oil, ultraviolet (UV) radiation, and temperature to determine how multiple stressors affect their survival. Compared to controls, exposed embryos floating near the ocean’s surface started to sink sooner and at faster rates, which intensified at higher temperatures.