Spelling suggestions: "subject:"salt harsh""
11 |
Population studies of Spartina anglica C.E. Hubbard in the Dee EstuaryHill, Margaret Irene January 1986 (has links)
No description available.
|
12 |
A comparison of invasive and non-invasive techniques for emasuring fiddler crab density in a salt marsh by Charles R. Hubbard.Hubbard, Charles Robert. January 2008 (has links) (PDF)
Thesis (M.S.)--Georgia Southern University, 2008. / "A thesis submitted to the Graduate Faculty of Georgia Southern University in partial fulfillment of the requirements for the degree Master of Science." Directed by Sophie B. George. ETD. INDEX WORDS: Fiddler crabs, Population density, Salt marsh, Survey techniques Includes bibliographical references (p. 28-30) and appendices.
|
13 |
A phytosociological study of the transition between salt marsh and terrestrial vegetation of Bahia de San QuintinNeuenschwander, Leon F. January 1972 (has links)
Thesis (M.A.)--California State College at Los Angeles, 1972. / Includes bibliographical references (leaves 31-33).
|
14 |
The role of sulfur in salt marsh metabolism /Howarth, Robert Warren. January 1979 (has links)
Thesis (Ph. D.)--Woods Hole Oceanographic Institution-Massachusetts Institute of Technology Joint Program in Biological Oceanography, 1979. / Includes bibliographical references.
|
15 |
Inter- and intraspecific variation in carbon and nutrient pools of salt marsh plantsElsey-Quirk, Tracy. January 2010 (has links)
Thesis (Ph.D.)--University of Delaware, 2009. / Principal faculty advisors: John L. Gallagher, and Denise M. Seliskar, School of Marine Science & Policy.. Includes bibliographical references.
|
16 |
Environmental change in San Francisco Estuary tidal marshesWatson, Elizabeth Burke. January 2006 (has links)
Thesis (Ph. D.)--University of California, Berkeley, 2006. / Includes bibliographical references.
|
17 |
Sodium-induced stomatal closure in the maritime halophyte Aster tripolium (L.)Robinson, Michael Frederick January 1996 (has links)
No description available.
|
18 |
Morphodynamic responses of salt marshes to sea-level rise: upland expansion, drainage evolution, and biological feedbacksFarron, Sarah Jean 11 December 2018 (has links)
Accelerating sea-level rise (SLR) poses an imminent threat to salt marshes, which sit within meters of mean sea level. In order to assess marsh vulnerability to SLR, we must first understand the fundamental processes governing marsh response to SLR. The objective of this dissertation work is to examine how marsh sedimentation and erosion affect the morphological development of marshes as sea level rises, over a broad range of spatial and temporal scales.
At the smallest scale, the effects of bioturbation by Sesarma reticulatum crabs on sediment erodibility are examined using a laboratory flume. Measurements of surface elevation, erosion, and turbidity show that S. reticulatum bioturbation repackages formerly compacted sediment and deposits it above the surface, decreasing the threshold velocity for erosion and increasing eroded volume. S. reticulatum-induced sediment erosion can have broader impacts on creek development and marsh morphology.
S. reticulatum has facilitated drainage network expansion in salt marshes at Sapelo Island, GA and Cape Romain, SC in response to local SLR. Burrowing by this crab directly adjacent to tidal creeks at these locations leads to rapid headward growth. The effects of site-specific conditions on creek expansion are examined through comparison of sediment properties, surface elevations, and historical rates of creek growth at each site. Results suggest that while similar processes are occurring at both locations, the higher elevation of the marsh in GA leads to greater shear strength and a larger volume of material to be eroded by creeks. These combined effects have led to slower creek growth compared to SC.
At the largest spatial scale, and projecting forward over a 100-year period, a model for marsh response to SLR at the Great Marsh in Massachusetts is developed. This model takes into account limitations imposed by both low sediment availability and steep topography in the surrounding uplands. Results indicate that while the marsh may persist for several decades, it undergoes a dramatic shift in ecology and hydrology. As the rate of SLR accelerates, marsh loss increases due to the lack of sediment available for accretion and the physical barriers to migration presented by surrounding topography.
|
19 |
Hydrodynamic effects of salt marsh canopies and their prediction using remote sensing techniquesTempest, James Alexander January 2017 (has links)
The aim of this thesis was to improve our understanding of plant – flow interactions and to develop new remote sensing techniques that would allow a marsh scale assessment of flow modification due to the presence of salt marsh vegetation. The limitations of current approaches which improve our understanding and prediction of tidal flows centre around poor assessments of canopy structure and mechanical properties. The validity of such simplified and reductionist assessments of canopy structure were tested and found to contribute considerable error in estimations of canopy frontal area and canopy drag. New metrics to assess canopy structure were tested as part of a flume study using two salt marsh species with varying form and architecture. Results from this experiment found that biomass located immediately below the water surface are important for determining fluid momentum losses in salt marsh canopies. These results led to the development of a new empirical based model using vertical measures of biomass and approach (incident) velocity which can accurately (R2 0.71) predict flow momentum losses. This suggests that the characteristic vegetation parameter and the drag coefficient may be substituted with vertical canopy biomass and an empirical coefficient. This may lead to more accurate assessments of canopy structure and thus comparable results across the literature as well as potentially apriori assignment of parameters in the force drag model. Vertical canopy biomass (3D biomass) was then estimated at the marsh scale using a combined remote sensing approach and an empirical model. Accurate assessments of the marsh surface are critical for hydrodynamic models and important if we are to determine vertical changes in canopy structure. The approach first identified marsh surface returns by operating a moving average smoothing filter on Airborne Laser Scanning (ALS) data. The automated procedure detected vegetated and non–vegetated surfaces using aerial NDVI which calibrated the filter and ensured ALS returns were representative of marsh surface elevation. Using the marsh surface DEM, vegetation was reconstructed at 0.2 m grid cells. Terrestrial Laser Scanning (TLS) was found to accurately quantify maximum canopy height (RMSE 0.14m) whilst a regression model using aerial NDVI and spatial coordinates gave reasonable predictions (RMSE 0.08kg/m2) of total plot canopy biomass within each 0.2 m cell across a ~20,000 m2 area of marsh. Ground measurements found the vertical distribution of canopy biomass followed a power law increase with elevation from the marsh bed. Combining all the approaches allowed the creation of a 3D assessment of canopy biomass with an average error of 30% of the mean amongst plots exhibiting larger canopy biomass ( > 0.4 kg/m2). This vertical measure of biomass can be combined with the flow momentum loss model generated in the flume experiment to assess hydrodynamic canopy drag potential at the marsh scale. Roughness coefficients can also be calculated using this approach which can be easily fed into commercially available numerical flow models.
|
20 |
Economic-ecological relationships in coastal wetland restoration /Magnusson, Gisele Marie. January 2006 (has links)
Thesis (Ph. D.)--University of Rhode Island, 2006. / Typescript. Includes bibliographical references (leaves 178-197).
|
Page generated in 0.0422 seconds