Jessica Aukamp scite author profile

Thalassia testudinum belowground biomass weights, leaf weights, leaf growth rates, areal shoot densities (m (2 ), and leaf C:N:P ratios were compared to a set of biogeochemical parameters to gain information on seagrassÁsediment interactions that may influence seagrass growth. Data were compiled from three surveys conducted in Santa Rosa Sound, located in northwest Florida, at three different meadows in sequential years. Biomass measurements and leaf growth rates decreased between stations along transects from shallow to deeper water. Belowground biomass weights decreased and leaf C:P ratios increased with temperature reflecting a seasonal growth pattern. The T. testudinum parameters were highly correlated with each other. Sulfate reduction rates (at times exceeding 1000 nmol ml (1 day (1 ) were among the highest recorded for seagrass beds with temperature accounting for 79% of the variation. Even though sulfate reduction rates were high, total Fe:reduced S ratios indicated sufficient Fe to account for all reduced S as pyrite. Sediment Fe, C, N, and organic P concentrations increased with sediment depth, whereas inorganic P decreased with depth, suggesting burial of organic P and root uptake of inorganic P. Leaf C:N:P ratios indicated P-limited growth for two surveys. NH 4 ' was detected in water above the sediment surface during some surveys demonstrating T. testudinum meadows at times may serve as sources of inorganic N to the water column. Plant parameters correlated with concentrations of sediment organic C and N, Fe, S, and porewater NH 4 ' . These results highlight the importance of the organic matter and Fe contents of sediments to seagrass growth.

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Spatially variable bioturbation and physical mixing drive the sedimentary biogeochemical seascape in the Louisiana continental shelf hypoxic zone

Devereux

Lehrter

Cicchetti

et al. 2019

Biogeochemistry

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Seasonal hypoxia on the Louisiana continental shelf (LCS) has grown to over 22,000 km 2 with limited information available on how low oxygen effects the benthos. Benthic macrofaunal colonization and sediment biogeochemical parameters were characterized at twelve stations in waters 10-50 m deep along four transects spanning 320 km across the LCS hypoxic zone in the early fall of 2010 when bottom waters typically return to oxic conditions. Chemical data and sediment profile imaging (SPI) support three primary mechanistic pathways of organic matter degradation on the LCS: (i) metal oxide cycling in depositional muds, (ii) infauna-driven bioturbation delivering oxygen below the sediment-water interface, and (iii) sulfate reduction in sediments where iron oxide availability is limited. The transect nearest the Mississippi River delta had the highest concentrations of porewater and solid phase Mn and Fe with SPI images of recently deposited reddish, mixed muddy sediments suggestive of metal cycling. The deepest stations had high oxidized iron concentrations and rust colored sediments with faunal colonization that suggests sediments are oxidized via bioturbation. Many nearshore and central LCS stations had more black sediments, more disturbed clay layers, lower amounts of oxidized iron, and higher sulfate reduction rates than the deepest stations. Sediment mixing coefficients, D B , determined from chlorophyll-a concentration profiles varied between 33 and 183 cm −2 y −1. D B values were highest at the deepest stations where sediments were colonized. D B were not determined at two *

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Northern Gulf of Mexico estuarine coloured dissolved organic matter derived from MODIS data

Schaeffer

Conmy

Duffy

et al. 2015

International Journal of Remote Sensing

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Characterizing light attenuation within Northwest Florida Estuaries: Implications for RESTORE Act water quality monitoring

Conmy

Schaeffer

Schubauer‐Berigan

et al. 2017

Marine Pollution Bulletin

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Water Quality (WQ) condition is based on ecosystem stressor indicators (e.g. water clarity) which are biogeochemically important and critical when considering the Deepwater Horizon oil spill restoration efforts under the 2012 RESTORE Act. Nearly all of the proposed RESTORE projects list restoring WC as a goal, but 90% neglect water clarity. Here, dynamics of optical constituents impacting clarity are presented from a 2009-2011 study within Pensacola, Choctawhatchee, St. Andrew and St. Joseph estuaries (targeted RESTORE sites) in Northwest Florida. Phytoplankton were the smallest contribution to total absorption (aPAR) at 412nm (5-11%), whereas colored dissolved organic matter was the largest (61-79%). Estuarine aPAR was significantly related to light attenuation (KPAR), where individual contributors to clarity and the influence of climatic events were discerned. Provided are conversion equations demonstrating interoperability of clarity indicators between traditional State-measured WQ measures (e.g. secchi disc), optical constituents, and even satellite remote sensing for obtaining baseline assessments.

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Organic and inorganic matter in Louisiana coastal waters: Vermilion, Atchafalaya, Terrebonne, Barataria, and Mississippi regions

Schaeffer

Conmy

Aukamp

et al. 2011

Marine Pollution Bulletin

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Jessica Aukamp

Interactions ofThalassia testudinumand sediment biogeochemistry in Santa Rosa Sound, NW Florida

Spatially variable bioturbation and physical mixing drive the sedimentary biogeochemical seascape in the Louisiana continental shelf hypoxic zone

Northern Gulf of Mexico estuarine coloured dissolved organic matter derived from MODIS data

Characterizing light attenuation within Northwest Florida Estuaries: Implications for RESTORE Act water quality monitoring

Organic and inorganic matter in Louisiana coastal waters: Vermilion, Atchafalaya, Terrebonne, Barataria, and Mississippi regions

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