Your search keyword '"Ron I. Eytan"' showing total 2 results

1. A Multidisciplinary Approach to Investigate Deep-Pelagic Ecosystem Dynamics in the Gulf of Mexico Following Deepwater Horizon

Author

April B. Cook, Andrea M. Bernard, Kevin M. Boswell, Heather Bracken-Grissom, Marta D’Elia, Sergio deRada, Cole G. Easson, David English, Ron I. Eytan, Tamara Frank, Chuanmin Hu, Matthew W. Johnston, Heather Judkins, Chad Lembke, Jose V. Lopez, Rosanna J. Milligan, Jon A. Moore, Bradley Penta, Nina M. Pruzinsky, John A. Quinlan, Travis M. Richards, Isabel C. Romero, Mahmood S. Shivji, Michael Vecchione, Max D. Weber, R. J. David Wells, and Tracey T. Sutton

Subjects

micronekton, epipelagic, mesopelagic, bathypelagic, sampling, hydrography, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

The pelagic Gulf of Mexico (GoM) is a complex system of dynamic physical oceanography (western boundary current, mesoscale eddies), high biological diversity, and community integration via diel vertical migration and lateral advection. Humans also heavily utilize this system, including its deep-sea components, for resource extraction, shipping, tourism, and other commercial activity. This utilization has had impacts, some with disastrous consequences. The Deepwater Horizon oil spill (DWHOS) occurred at a depth of ∼1500 m (Macondo wellhead), creating a persistent and toxic mixture of hydrocarbons and dispersant in the deep-pelagic (water column below 200 m depth) habitat. In order to assess the impacts of the DWHOS on this habitat, two large-scale research programs, described herein, were designed and executed. These programs, ONSAP and DEEPEND, aimed to quantitatively characterize the oceanic ecosystem of the northern GoM and to establish a time-series with which natural and anthropogenic changes could be detected. The approach was multi-disciplinary in nature and included in situ sampling, acoustic sensing, water column profiling and sampling, satellite remote sensing, AUV sensing, numerical modeling, genetic sequencing, and biogeochemical analyses. The synergy of these methodologies has provided new and unprecedented perspectives of an oceanic ecosystem with respect to composition, connectivity, drivers, and variability.

Published

2020

2. A Multidisciplinary Approach to Investigate Deep-Pelagic Ecosystem Dynamics in the Gulf of Mexico Following Deepwater Horizon

Author

Heather D. Bracken-Grissom, Matthew W. Johnston, Heather Judkins, Marta D’Elia, Nina Pruzinsky, Jose V. Lopez, David English, Sergio deRada, Andrea M. Bernard, Ron I. Eytan, Kevin M. Boswell, R. J. David Wells, Mahmood S. Shivji, Isabel C. Romero, Jon A. Moore, Travis M. Richards, John A Quinlan, Rosanna Milligan, Cole G. Easson, April Cook, Chad Lembke, Max Weber, Tamara Frank, Michael Vecchione, Chuanmin Hu, Bradley Penta, and Tracey T. Sutton

Subjects

0106 biological sciences, sampling, Biogeochemical cycle, lcsh:QH1-199.5, 010504 meteorology & atmospheric sciences, Ocean Engineering, bathypelagic, lcsh:General. Including nature conservation, geographical distribution, Aquatic Science, Physical oceanography, Oceanography, 01 natural sciences, Water column, hydrography, mesopelagic, Ecosystem, lcsh:Science, Diel vertical migration, 0105 earth and related environmental sciences, Water Science and Technology, Global and Planetary Change, Ecosystem health, 010604 marine biology & hydrobiology, micronekton, Pelagic zone, epipelagic, Environmental science, lcsh:Q, Hydrography

Abstract

The pelagic Gulf of Mexico (GoM) is a complex system of dynamic physical oceanography (western boundary current, mesoscale eddies), high biological diversity, and community integration via diel vertical migration and lateral advection. Humans also heavily utilize this system, including its deep-sea components, for resource extraction, shipping, tourism, and other commercial activity. This utilization has had impacts, some with disastrous consequences. The Deepwater Horizon oil spill (DWHOS) occurred at a depth of ∼1500 m (Macondo wellhead), creating a persistent and toxic mixture of hydrocarbons and dispersant in the deep-pelagic (water column below 200 m depth) habitat. In order to assess the impacts of the DWHOS on this habitat, two large-scale research programs, described herein, were designed and executed. These programs, ONSAP and DEEPEND, aimed to quantitatively characterize the oceanic ecosystem of the northern GoM and to establish a time-series with which natural and anthropogenic changes could be detected. The approach was multi-disciplinary in nature and included in situ sampling, acoustic sensing, water column profiling and sampling, satellite remote sensing, AUV sensing, numerical modeling, genetic sequencing, and biogeochemical analyses. The synergy of these methodologies has provided new and unprecedented perspectives of an oceanic ecosystem with respect to composition, connectivity, drivers, and variability.

Published

2020