|
|
Graduate Student Research at the Florida Coastal Everglades LTER Site
"Decomposition of Cladium jamaicense and Eleocharis spp. in
the ecotone regions of Taylor Slough and Shark River Slough"
by Gustavo Rubio, Department of Biology, Florida International University
A project that combines science and technology can obtain superior results
than one that just includes one or the other. This project is set to mix
science and technology to measure the ecosystem process of decomposition
for two predominant macrophyte species Cladium jamaicense and Eleocharis
spp.. The project is to take place in the ecotone regions of Shark River
Slough and Taylor Slough located in the Everglades National Park (ENP).
The ecotone regions of both sloughs experience a mixing between fresh
water and salt water that makes them unique from all the other regions
found in the sloughs.
Decomposition rates for Cladium jamaicense and Eleocharis spp. will be
measured by using litter bags which contains dead plant material for both
species. Litter bags will experience three different treatments
- open air to account for decomposition of leaves before they are shed
by the plant,
- soil surface to account for decomposition once the leaves have been
shed by the plant and reach the soil surface, and
- macroinvertebrates in which the mesh size of the litter bags will
be bigger to allow macroinvertebrates in the bags. Three bags from each
treatment will be collected after 0, 1, 2, 4, 6, 12, and 18 months.
- Two scenes from NASA Airborne Visible InfraRed Imaging Spectrometer
(AVIRIS) hyperspectral sensor will be used to measure nitrogen and lignin
content, which are important components that determine leaf litter decomposition,
in dead Cladium jamaicense leaves for both ecotone regions. The results
of this project will be useful for management and restoration project
that are being done in the ENP.
"Investigating tree island community response to increased water
flow in a Southeastern Everglades ecosystem"
by Tiffany Gann, Department of Biology, Florida International University
Tree island communities have a distinct flora and are likely to be functionally
different from the Everglades marsh community. This experiment takes advantage
of levee removal in the southern Everglades as a part of the hydrologic
restoration of freshwater flow to Florida Bay.
We are utilizing three treatment groups:
1) islands that are most affected by increased water flow as a result
of levee removal;
2) islands that are located in an area of the marsh where increased freshwater
flow is negligible, and; 3) an experimental manipulation in which freshwater
flow is diverted with plastic walls. With this experimental design, we
will test how tree island communities respond to long-term changes in
water flow, and also determine the trajectory for tree island community
response.
To investigate these effects, we are quantifying plant community structure,
plant productivity, litterfall production, nutrient use efficiency, litter
decomposition and soil biogeochemical properties of nine tree island communities.
"Primary Productivity, Periphyton metabolism"
by David Iwaniec Department of Biology, Florida International University
|
FCE graduate student Ralph Mead working at on of the Taylor Slough
mangrove sites
|
We are studying patterns and magnitudes of periphyton metabolic responses
to reveal local system reactions to spatial and water source effects.
Our study sites are within the Southern Everglades, along marsh transects
anchored at the C-111 canal and extending into Taylor Slough to Florida
Bay. We will quantify metabolic rates of periphyton assemblages using
standard oxygen change techniques every 6-8 weeks during the wet season.
Biannually, periphyton from each site is incubated with water from each
site in a complete factorial design.
Origin, Transport and Fate of Organic Matter From the Florida Coastal
Everglades: An Organic Geochemical Approach
Ralph Mead, Environmental Geochemistry Group, Department of Chemistry,
Florida International University
Organic matter dynamics in small sub-tropical estuaries have not been
studied in great detail. The Florida Everglades are one of the largest
coastal wetlands in the world, and drain a significant amount of water
into the coastal environment of South Florida. As such small sub-tropical
estuaries are a key component of this ecosystem. Two such estuaries, namely
the Shark and Taylor River Estuaries are characterized by quite different
hydrological conditions. They are expected to be affected differently
by the restoration efforts of the Everglades. While the main goal of our
LTER is to predict, monitor and model such changes, this particular study
is aimed at the effects on the carbon cycling in these estuaries. Therefore,
spatial and temporal variations in organic matter quality and quantity,
and its source, fate and transport to both of the estuaries will be investigated.
The study is based on the analysis of transect samples from both estuaries,
subject to GC/MS for molecular marker analysis, analysis of bulk sediment/soil
parameters (C/N , TOC, TSS, solid state CP-MAS 13C NMR) and bulk and compound
specific 13C stable isotope ratio monitoring mass spectrometry
|
