Browsing by Subject "Seabirds"
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Item Open Access A long-term temporal analysis of heavy metal concentrations in seabird feathers with implications for overgeneralized trophic dynamics(2019-04-26) Johnson, ElizabethAnthropogenic deposition and natural cycling of heavy metal can impact ecosystem function: They can accumulate in marine sediment layers and remain there for long periods of time. As these metals accumulate and move through the ecosystem to higher trophic level organisms, these metals have known toxic effects including decreased reproductive success and compromised immune systems. Seabird feather levels may be representative of broader ecosystem signals and heavy metal cycling. This study combines heavy metal concentration data from seabird feathers and builds on the results of previous studies looking at trophic declines across time. The aim is to emphasize the importance of tracking trophic levels of top predators, looking at heavy metal concentrations from the 1880s to 2016, as well as carbon and nitrogen stable isotopes to determine if changing trophic levels will alter estimated trends and environmental heavy metal concentrations. We present temporal trends in seabird tissue concentration, and examine the complex field of trophic transfer, proposing a protocol for interpreting environmental concentrations. Our results show that trophic declines do not drastically impact directional trends, but that extrapolating to other trophic levels creates a large margin of uncertainty. We observe declines in heavy metals that correspond with relevant legislation, and suggest further studies into lesser known metals to strengthen environmental monitoring methods.Item Open Access Conservation Through Population Assessments Across Variable Landscapes(2019) Huang, RyanFew areas of the planet are untouched by human actions, be they marine or terrestrial. Marine habitats face disturbance from overexploitation of fisheries and pollution while terrestrial habitats face significant threat from land cover conversion and degradation. To address these threats, conservationists utilize a variety of population viability analyses to both assess and manage species’ health. The results of these analyses often play a key role in determining when intervention is necessary and which actions will be the most successful. Within this dissertation, I used several population modeling approaches to advance our understanding of changes in the landscape on the persistence of populations and by extension, species.
This dissertation may be broadly divided into two halves, the first assessing a single, local population and the second evaluating metapopulations. In Chapter 2, I combined telemetry data on sooty terns (Onychoprion fuscatus) with a long-term capture-mark-recapture dataset from the Dry Tortugas National Park to map the movements at sea for this species, calculate estimates of mortality, and investigate the impact of hurricanes on a migratory seabird. Included in the latter analysis is information on the locations of recovered bands from deceased individuals wrecked by tropical storms. I present the first known map of sooty tern migration in the Atlantic Ocean. The results indicate that the birds had minor overlaps with areas affected by the major 2010 oil spill and a major shrimp fishery. Indices of hurricane strength and occurrence are positively correlated with annual mortality and indices of numbers of wrecked birds. As climate change may lead to an increase in severity and frequency of major hurricanes, this may pose a long-term problem for this colony.
In the latter half of this dissertation, I utilized a variety of metapopulation analyses for conservation at multiple scales. As a landscape becomes increasingly fragmented through habitat loss, the individual patches become smaller and more isolated and thus less likely to sustain a local population. Metapopulation theory is appropriate for analyzing fragmented landscapes because it combines empirical landscapes features with species-specific information to produce direct information on population extinction risks. Combining a spatially explicit metapopulation model with empirical data on endemic species’ ranges and maps of habitat cover, I could calculate the metapopulation capacity— a measure of a landscape’s ability to sustain a metapopulation.
Mangroves provide an ideal, model landscape for my analysis in Chapter 3. Of conservation concern, one can easily delineate their patch boundaries. I calculated metapopulation capacity for 99 metapopulations from 32 different mangrove-endemic bird species globally in the years 2000 and 2015. Northern Australia and South East Asia have the highest richness of mangrove-endemic birds, with some hotspots also occurring in Guyana and French Guiana. The areas with the highest metapopulation loss are the Caribbean, the Pacific coast of Central America, Madagascar, Borneo, and isolated patches in Southeast Asia in Burma and Malaysia. Regions with the highest loss of habitat area are not necessarily those with the highest loss of metapopulation capacity. Often it is not a matter of how much, but how the habitat is lost since fragmentation of patches has a complicated relationship with extinction risk.
After analyzing the effects of habitat loss and fragmentation on a species’ risk of extinction, it is natural to examine the reverse, the restoration of habitat. In Chapter 4, I used metapopulation models to prioritize locations for potential habitat corridors. I compared these results to standard connectivity models that have grown in popularity to illustrate how together they provide a more complete set of recommendations for the recovery of species. For this chapter, I use the golden lion tamarin (Leontopithecus rosalia) as the focal species. Endemic to the highly fragmented Atlantic coastal forest of Brazil, the golden lion tamarins are a highly studied species of top conservation concern. I identified the best locations for habitat restoration to increase metapopulation capacity and how they compare with movement of individuals in the current landscape. I also evaluated how a previous corridor restoration ranked according to these methods and how it effects future conservation planning. While large, occupied patches are significant for both sets of models, metapopulation models also indicate the importance of nearby, medium-sized empty patches that if connected by a corridor would facilitate the growth and recovery of tamarin populations.
In summary, I applied a suite of population modeling techniques to an assortment of landscapes and species for conserving biodiversity. Despite the variety of models used, I illustrate the flexibility and utility of population ecology to conservation management.
Item Open Access DISTRIBUTION OF HIGHLY MIGRATORY MARINE MAMMALS AND SEABIRDS IN THE EASTERN NORTH PACIFIC: ARE EXISITNG MARINE PROTECTED AREAS IN THE RIGHT PLACE?(2003) Freeman, KateTo date, only five marine protected areas (MPAs) have been established along the West Coast of the United States, none of which extend more than 30 nautical miles from shore. These areas do not afford habitat protection for a number of highly migratory and often endangered pelagic seabird and cetacean species found in the Northeastern Pacific Ocean. Using sightings data for fourteen species from a Minerals Management Service Computer Database Analysis System, I analyzed species distribution based on oceanographic season (countercurrent, upwelling, oceanic), year (El Nino, La Nina, neutral), patchiness, bathymetry (shelf, shelf-break, slope, pelagic), and index of dispersion (Gx). The species density data were also compared to areas of existing MPAs to determine how well current MPAs protect these species. The results indicate that current MPAs do not protect the habitats of highly migratory species. I therefore compared existing MPA coverage to suggested MPA locations and found much stronger protection in the suggested areas. Recommendations include not only general areas for improved protection, such as the North Bend, Oregon region, but also specific season and bathymetric features to protect as hotspots within the larger regions.Item Open Access Pacific Island Fisheries and Interactions with Marine Mammals, Seabirds and Sea Turtles(2009-04-24T15:06:07Z) Aylesworth, LindsayThe extent to which Pacific Island fisheries affect marine mammals, sea turtles, and seabirds due to bycatch remains largely unknown. This report attempts to synthesize the existing information relating to fisheries and bycatch of marine mammals, sea turtles, and sea birds in the Pacific Island countries and territories. The Oceania region encompasses the 22 Pacific Island countries and territories including Papua New Guinea (PNG), but excluding Hawaii, New Zealand, and Australia. Tuna is the most important commercial fishery with four target species (albacore, bigeye, skipjack, and yellowfin) and four distinct gear types (purse seine, longline, pole and line, and trollers) (Gillett, 2008). The subsistence and artisanal fisheries located inshore are largely unregulated with little to no monitoring of catch or effort. Bycatch would be extremely difficult to monitor in these fisheries as seabirds, turtles and even some marine mammals are consumed traditionally throughout the Pacific Islands and any unintentional catch would be retained and consumed. Despite efforts in certain areas and on several species, e.g., humpback whales, detailed knowledge of marine mammals, seabirds and sea turtles is at best extremely limited. The only bycatch mortality estimates are from the commercial tuna fishery indicating around 265 marine mammals, 100 seabirds and 900 sea turtles are killed per year (Molony 2005). The main challenge to identifying and quantifying bycatch of sea turtles is the lack of observer coverage. Information on population structure and occurrence of marine mammals, sea turtles, and seabirds in the region should be a priority. Bycatch language should be written into national tuna management programs and industry should be involved in discussions to mitigate bycatch at the WCPFC. Other recommendations include research into the catch and effort in subsistence and small-scale fisheries as well as mandatory workshops for commercial vessel owners on bycatch handling and training as part of a licensing scheme.Item Open Access Sooty tern (Onychoprion fuscatus) survival, oil spills, shrimp fisheries, and hurricanes.(PeerJ, 2017-01) Huang, Ryan M; Bass, Oron L; Pimm, Stuart LMigratory seabirds face threats from climate change and a variety of anthropogenic disturbances. Although most seabird research has focused on the ecology of individuals at the colony, technological advances now allow researchers to track seabird movements at sea and during migration. We combined telemetry data on Onychoprion fuscatus (sooty terns) with a long-term capture-mark-recapture dataset from the Dry Tortugas National Park to map the movements at sea for this species, calculate estimates of mortality, and investigate the impact of hurricanes on a migratory seabird. Included in the latter analysis is information on the locations of recovered bands from deceased individuals wrecked by tropical storms. We present the first known map of sooty tern migration in the Atlantic Ocean. Our results indicate that the birds had minor overlaps with areas affected by the major 2010 oil spill and a major shrimp fishery. Indices of hurricane strength and occurrence are positively correlated with annual mortality and indices of numbers of wrecked birds. As climate change may lead to an increase in severity and frequency of major hurricanes, this may pose a long-term problem for this colony.Item Open Access Top Predator Distribution and Foraging Ecology in Florida Bay, Florida(2007-11-14) Torres, Leigh GabrielaThe heterogeneous landscape of Florida Bay provides habitats for a variety of predators and prey. This dissertation examined the bottom-up transfer of affects from environmental variability through prey composition up to competition and predation affects on top predator distribution and foraging ecology in Florida Bay. Line transect surveys for bottlenose dolphins and seabirds were conducted in Florida Bay during the summer months of 2002 - 2005. Photo-identification techniques were implemented to identify individual dolphins. Synoptic with this survey effort, habitat characteristics (temperature, salinity, dissolved oxygen, turbidity, chlorophyll a, depth and bottom type) and prey composition (bottom trawl or gillnet) were sampled. Comparison of envelope maps from generalized additive models determined that predictive capacity of dolphin habitat did not improve by incorporating fish distribution data. However, models of dolphin distribution based solely on environmental proxies of fish distribution resulted in high predictive capacity. During the 2005 summer, shark distribution was sampled using a longline. The abundance of sharks was only correlated to fish catch from trawls on a regional scale. Larger sharks, of species that may threaten dolphins, were only caught in the Gulf zone of the Bay. Analysis of dolphin distribution revealed high individual site and foraging tactic fidelity. Dolphins were spatially coincident with habitat characteristics that encouraged the use of each individual's preferred foraging tactic. Depth was identified as the primary variable determining dolphin foraging tactic choice. Depth plays a significant role in the benthic composition of Florida Bay, which subsequently impacts prey communities and affects dolphin distribution, foraging and social ecology. Ordinations determined that fish distribution was also principally affected by depth and bottom type. Shallow environments frequently corresponded with mudbank habitat (depth < 1m) where the sighting rates of seabirds (cormorants, osprey, pelicans, terns) and foraging dolphins peaked. In conclusion, subtle relief in South Florida's bedrock topography dramatically affect benthic composition within Florida Bay, providing patchy habitats for prey and predators. The Florida Bay ecosystem will change with expected sea level rise, including spatial shifts of mudbank habitats. Top predator populations in Florida Bay will be forced to modify their distribution and foraging ecology accordingly.