Global ETD Search

141	Modeling Survival Of Immature Loggerheads (caretta Caretta) And Green Turtles (chelonia Mydas) From 10 Years Of Mark-recapture Data At The Florida Power And Light St. Lucie Plant Sterner, Andrew 01 January 2013 (has links) Loggerheads (Caretta caretta) are listed as Threatened and green turtles (Chelonia mydas) are listed as Endangered under the United States Endangered Species Act. While green turtle nest production in Florida has increased markedly in recent years, loggerhead nest production has followed a more tenuous path. Reasons for these differences are unknown. Limited demographic information is available for these species of conservation concern. I used Barker models, which incorporated mark-recapture, live-resight and dead recovery data, implemented in Program MARK. These models were used to estimate apparent survival for immature loggerhead ( Green turtles loggerheads mark recapture barker models survivorship demography Biology
142	Sex Ratios Of Juvenile Green Turtles (chelonia Mydas) In Three Developmental Habitats Along The Coast Of Florida Sanchez, Cheryl 01 January 2013 (has links) The concept of temperature dependent sex determination (TSD) has been somewhat of an evolutionary enigma for many decades and has had increased attention with the growing predictions of a changing climate, particularly in species that are already threatened or endangered. TSD taxa of concern include marine turtles, which go through various life stages covering a range of regions. This, in turn, creates difficulties in addressing basic demographic questions. Secondary sex ratios (from life stages post-hatchling) were investigated by capturing juvenile green turtles (Chelonia mydas), 22.6-60.9 cm in straight carapace length (SCL), from three developmental areas along the east coast of Florida (a region known to have important juvenile aggregations) by analyzing circulating testosterone levels. All three aggregations exhibited significant female biases with an overall ratio of 3.2:1 (female: male). The probability of a turtle being female increased as the size of the individual decreased. Ratios obtained in this study were slightly less female-biased, but not significantly different, than those observed in the late 1990s. However, they were significantly more biased than those found in a late 1980s pilot study. The shift to significantly female-biased ratios may be beneficial to a recovering population, an evolutionary adaptation, and is common among juvenile aggregations. A more skewed female bias in smaller size classes may be indicative of recent, warmer periods during incubation on the nesting beaches. This female bias could become more exaggerated if temperatures meet future climate warming predictions. Chelonia mydas climate change marine turtles ria sex ratios Biology
143	DISCOVERING SEAGRASS BLUE CARBON RESOURCES IN THE RED SEA BY GREEN TURTLE Chelonia mydas TRACKING Mann, Hugo F. 27 November 2022 (has links) Seagrass is a valuable and important habitat, providing services such as coastal protection, supporting fisheries, and carbon sequestration. However, it is challenging to map accurately, as remote sensing has limits to how deep in the water column it can penetrate, and uncertainties such as distinguishing between algae and seagrass. Seagrass can exist at depths of theoretically 90 m deep in ultraoligotrophic waters, meaning that there is much of this habitat that cannot be mapped by remote sensing. Green turtles are an ideal candidate to help find seagrass blue carbon resources in the Red Sea. They go through an ontogenetic dietary shift to become almost completely herbivorous, and have a high fidelity to foraging sites. In this study we aim to assess the use of green turtles Chelonia mydas in discovering seagrass blue carbon. We use telemetry from 53 turtles tagged over 2018, 2019, and 2021 to map their foraging areas. 50 out of the 53 (94.34%) foraging sites had not been visited by previous seagrass studies in the Red Sea. We visited 18 locations in 14 of these foraging sites to ground truth them, and all 14 foraging sites (100%) had seagrass present. Comparatively, 18 out of 30 sites where seagrass was indicated by the remote sensing-based Allen Coral Atlas showed no seagrass. The turtles were seen to favour travelling shorter distances, thus it will be necessary to expand the area of tagging in order to achieve complete coverage of the Red Sea. Approximately 1/3 of the visited sites were deeper than 8 m, and so out of range of remote sensing, showing that considerable blue carbon resources may be discovered with the use of turtles. Samples were taken for carbon stock estimation from the ground truthed sites. A mean carbon stock of 4.89 ± 0.83 kg Corg m-2 was estimated for 1 m depth sediment. In the future it is important to develop methods for mapping the surface areas of the deep and inaccessible seagrass habitats that the turtles discover. Seagrass Blue carbon Green turtles Chelonia mydas mapping carbon stocks
144	ECOLOGICAL PHYSIOLOGY OF OVERWINTERING IN HATCHLING BLANDING’S TURTLES (Emydoidea blandingii): INSIGHTS INTO ANOXIA TOLERANCE AND FREEZE TOLERANCE Dinkelacker, Stephen 29 July 2004 (has links) No description available. Biology, Animal Physiology HATCHLING TURTLES blandingii ANOXIA freezing lactate serpentina
145	Sublethal effects of stressors on physiological and morphological parameters in the diamondback terrapin, <em>Malaclemys terrapin</em> Ford, Dawn K. 19 April 2005 (has links) No description available. Biology, Animal Physiology Growth Metabolic Rate Corticosterone PCB 126 Turtles
146	THE ECOLOGY OF DEVELOPMENTAL TIMING IN A NEOTROPICAL TURTLE, KINOSTERNON LEUCOSTOMUM Horne, Brian D. 25 September 2007 (has links) No description available. Biology, Ecology ecology embryonic diapause turtles Kinosternon Conservation
147	Locomotor kinematics of turtles moving in shallow water environments Mazouchova, Nicole January 2019 (has links) Locomotion, moving around in our complex world is as crucial to many animals as finding food, shelter or a mate. The intricate interplay between the brain, nerves, muscles, tendons and bones allows for a variety of gaits. Animal movement has been studied in many environments like water, land or air, often focusing on one habitat alone. These studies were crucial in establishing the principles of animal locomotion, but don’t always reflect the intricate lifestyle of an animal. More often then not, animals will encounter different surface structures (such as grass, sand, soil, forest debris) or even interact between different habitats, such as at the water-land interface. Fewer studies have focused on understanding how movement changes when physical conditions vary. A turtle swimming in a dense, buoyancy-dominated water habitat transitioning to a walking on gravity-dominated terrestrial habitat is poorly understood and may open insight into new locomotor strategies. Turtles are an interesting study subject to study water-land transitions, as their spines are fused to their carapace, isolating any movement generation to their limbs only. In this thesis, I chose different size red-eared slider (Trachemys scripta elegans) turtles to investigate their locomotion during discreet water depth, as well as during shallow water locomotion and investigated whether bone shape can be predictive of the environment they live in. / Biology Biomechanics Geometric Morphometrics Kinematics Turtles Water-land Transitions
148	Characterizing juvenile green turtles, (Chelonia mydas), from three east central Florida developmental habitats Bagley, Dean A. 01 July 2003 (has links) No description available. Biology
149	Sea turtle nutrient inputs to dune vegetation : a stable isotope analysis Plog, Laura Beth 01 January 2004 (has links) No description available. Sand dune ecology -- Florida Sea turtles -- Habitat -- Florida Biology
150	The role of air and waterborne odors in orientation and food detection in three species of marine turtles Unknown Date (has links) The cues used by marine turtles to locate foraging areas in the open ocean are largely unknown though some species (especially the green turtle [Chelonia mydas], the loggerhead [Caretta caretta], and the leatherback [Dermochelys coriacea]) somehow locate areas of high productivity. Loggerheads can detect airborne odors, but a capacity to orient has not yet been investigated. In this comparative study, tethered loggerheads and leatherbacks were exposed to dimethyl sulfide (DMS) or food odors in a laminar flow of air. Turtles did not orient into the air current. Free-swimming loggerheads and green turtles were also exposed to air- or waterborne food (squid) odor plus a neutral visual stimulus. Both species showed increases in swimming activity and biting behavior to both stimuli. These results suggest that airborne odors are likely not used to locate distant areas, but that they are used in localized food searching efforts. / Includes bibliography. / Thesis (M.S.)--Florida Atlantic University, 2014. / FAU Electronic Theses and Dissertations Collection Animal behavior Animal orientation Population genetics Predation (Biology) Sea turtles -- Habitat Sea turtles -- Life cycles Wildlife conservation

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