Ethan Goddard
University of South Florida
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PLOS ONE | 2015
Isabel C. Romero; Patrick T. Schwing; Gregg R. Brooks; Rebekka A. Larson; David W. Hastings; Greg Ellis; Ethan Goddard; David J. Hollander
The Deepwater Horizon (DWH) spill released 4.9 million barrels of oil into the Gulf of Mexico (GoM) over 87 days. Sediment and water sampling efforts were concentrated SW of the DWH and in coastal areas. Here we present geochemistry data from sediment cores collected in the aftermath of the DWH event from 1000 – 1500 m water depth in the DeSoto Canyon, NE of the DWH wellhead. Cores were analyzed at high-resolution (at 2 mm and 5 mm intervals) in order to evaluate the concentration, composition and input of hydrocarbons to the seafloor. Specifically, we analyzed total organic carbon (TOC), aliphatic, polycyclic aromatic hydrocarbon (PAHs), and biomarker (hopanes, steranes, diasteranes) compounds to elucidate possible sources and transport pathways for deposition of hydrocarbons. Results showed higher hydrocarbon concentrations during 2010-2011 compared to years prior to 2010. Hydrocarbon inputs in 2010-2011 were composed of a mixture of sources including terrestrial, planktonic, and weathered oil. Our results suggest that after the DWH event, both soluble and highly insoluble hydrocarbons were deposited at enhanced rates in the deep-sea. We proposed two distinct transport pathways of hydrocarbon deposition: 1) sinking of oil-particle aggregates (hydrocarbon-contaminated marine snow and/or suspended particulate material), and 2) advective transport and direct contact of the deep plume with the continental slope surface sediments between 1000-1200 m. Our findings underline the complexity of the depositional event observed in the aftermath of the DWH event in terms of multiple sources, variable concentrations, and spatial (depth-related) variability in the DeSoto Canyon, NE of the DWH wellhead.
Marine Pollution Bulletin | 2015
Ester Quintana-Rizzo; Joseph J. Torres; Steve W. Ross; Isabel C. Romero; Kathleen Watson; Ethan Goddard; David J. Hollander
The blowout of the Deepwater Horizon (DWH) drill-rig produced a surface oil layer, dispersed micro-droplets throughout the water column, and sub-surface plumes. We measured stable carbon and nitrogen isotopes in mesopelagic fishes and shrimps in the vicinity of DWH collected prior to, six weeks after, and one year after the oil spill (2007, 2010 and 2011). In 2010, the year of the oil spill, a small but significant depletion of δ(13)C was found in two mesopelagic fishes (Gonostoma elongatum and Chauliodus sloani) and one shrimp (Systellaspis debilis); a significant δ(15)N enrichment was identified in the same shrimp and in three fish species (G. elongatum, Ceratoscopelus warmingii, and Lepidophanes guentheri). The δ(15)N change did not suggest a change of trophic level, but did indicate a change in diet. The data suggest that carbon from the Deepwater Horizon oil spill was incorporated into the mesopelagic food web of the Gulf of Mexico.
Journal of Visualized Experiments | 2016
Patrick T. Schwing; Isabel C. Romero; Rebekka A Larson; Bryan J. O'Malley; Erika E. Fridrik; Ethan Goddard; Gregg R. Brooks; David W. Hastings; Brad E. Rosenheim; David J. Hollander; Guy Grant; Jim Mulhollan
Aquatic sediment core subsampling is commonly performed at cm or half-cm resolution. Depending on the sedimentation rate and depositional environment, this resolution provides records at the annual to decadal scale, at best. An extrusion method, using a calibrated, threaded-rod is presented here, which allows for millimeter-scale subsampling of aquatic sediment cores of varying diameters. Millimeter scale subsampling allows for sub-annual to monthly analysis of the sedimentary record, an order of magnitude higher than typical sampling schemes. The extruder consists of a 2 m aluminum frame and base, two core tube clamps, a threaded-rod, and a 1 m piston. The sediment core is placed above the piston and clamped to the frame. An acrylic sampling collar is affixed to the upper 5 cm of the core tube and provides a platform from which to extract sub-samples. The piston is rotated around the threaded-rod at calibrated intervals and gently pushes the sediment out the top of the core tube. The sediment is then isolated into the sampling collar and placed into an appropriate sampling vessel (e.g., jar or bag). This method also preserves the unconsolidated samples (i.e., high pore water content) at the surface, providing a consistent sampling volume. This mm scale extrusion method was applied to cores collected in the northern Gulf of Mexico following the Deepwater Horizon submarine oil release. Evidence suggests that it is necessary to sample at the mm scale to fully characterize events that occur on the monthly time-scale for continental slope sediments.
Environmental Pollution | 2018
Patrick T. Schwing; Jeffrey P. Chanton; Isabel C. Romero; David J. Hollander; Ethan Goddard; Gregg R. Brooks; Rebekka A. Larson
Following the Deepwater Horizon (DWH) event in 2010, hydrocarbons were deposited on the continental slope in the northeastern Gulf of Mexico through marine oil snow sedimentation and flocculent accumulation (MOSSFA). The objective of this study was to test the hypothesis that benthic foraminiferal δ13C would record this depositional event. From December 2010 to August 2014, a time-series of sediment cores was collected at two impacted sites and one control site in the northeastern Gulf of Mexico. Short-lived radioisotopes (210Pb and 234Th) were employed to establish the pre-DWH, DWH, and post-DWH intervals. Benthic foraminifera (Cibicidoides spp. and Uvigerina spp.) were isolated from these intervals for δ13C measurement. A modest (0.2-0.4‰), but persistent δ13C depletion in the DWH intervals of impacted sites was observed over a two-year period. This difference was significantly beyond the pre-DWH (background) variability and demonstrated that benthic foraminiferal calcite recorded the depositional event. The longevity of the depletion in the δ13C record suggested that benthic foraminifera may have recorded the change in organic matter caused by MOSSFA from 2010 to 2012. These findings have implications for assessing the subsurface spatial distribution of the DWH MOSSFA event.
Chemical Geology | 2012
Daniel J. Sinclair; Jay L. Banner; Frederick W. Taylor; Judson W. Partin; John W. Jenson; John E. Mylroie; Ethan Goddard; T. M. Quinn; John M. U. Jocson; Blaž Miklavič
Journal of Paleolimnology | 2008
Thomas J. Whitmore; Melanie A. Riedinger-Whitmore; Joseph M. Smoak; Keith V. Kolasa; Ethan Goddard; Richard Bindler
ACS symposium series | 2007
Luca Lai; Robert H. Tykot; Jessica F. Beckett; Rosalba Floris; Ornella Fonzo; Elena Usai; Maria Rosaria Manunza; Ethan Goddard; David J. Hollander
Préhistoires Méditerranéennes | 2013
Luca Lai; Robert H. Tykot; Elena Usai; Jessica F. Beckett; Rosalba Floris; Ornella Fonzo; Ethan Goddard; David J. Hollander; Maria Rosaria Manunza; Alessandro Usai
Current Approaches to Collective Burials in the Late European Prehistory: Procedings of the XVII UISPP World Congress (1-7 Septembre 2014, Burgos, Spain), 2017, ISBN 978-1-78491-721-0, págs. 67-78 | 2017
Luca Lai; Ornella Fonzo; Elena Usai; Luca Mecida; Robert H. Tykot; Ethan Goddard; David B. Hollander; Giuseppa Tanda
Archive | 2016
Isabel C. Romero; W. Patterson; Tracey Sutton; Ester Quintana-Rizzo; Steve W. Ross; A. Kane; S. Murawski; Ethan Goddard; Joseph J. Torres; David J. Hollander