Browsing by Author "Cimino, Megan A."
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Item Climate-driven sympatry may not lead to foraging competition between congeneric top-predators(Nature Publishing Group, 2016-01-06) Cimino, Megan A.; Moline, Mark A.; Fraser, William R.; Patterson-Fraser, Donna L.; Oliver, Matthew J.; Megan A. Cimino, Mark A. Moline, William R. Fraser, Donna L. Patterson-Fraser & Matthew J. Oliver; Cimino, Megan A.; Moline, Mark A.; Oliver, Matthew J.Climate-driven sympatry may lead to competition for food resources between species. Rapid warming in the West Antarctic Peninsula (WAP) is coincident with increasing gentoo penguin and decreasing Adélie penguin populations, suggesting that competition for food may exacerbate the Adélie penguin decline. On fine scales, we tested for foraging competition between these species during the chickrearing period by comparing their foraging behaviors with the distribution of their prey, Antarctic krill. We detected krill aggregations within the horizontal and vertical foraging ranges of Adélie and gentoo penguins, and found that krill selected for habitats that balance the need to consume food and avoid predation. In overlapping Adélie and gentoo penguin foraging areas, four gentoo penguins switched foraging behavior by foraging at deeper depths, a strategy which limits competition with Adélie penguins. This suggests that climate-driven sympatry does not necessarily result in competitive exclusion of Adélie penguins by gentoo penguins. Contrary to a recent theory, which suggests that increased competition for krill is one of the major drivers of Adélie penguin population declines, we suggest that declines in Adélie penguins along the WAP are more likely due to direct and indirect climate impacts on their life histories.Item Local- and large-scale effects of climate change on Pygoscelis penguin habitat and demography(University of Delaware, 2016) Cimino, Megan A.Climate change around Antarctica is coincident with shifts in the distribution and abundance of Pygoscelid penguins, understanding this link between penguins and climate is the motivation behind this dissertation. I conducted two studies at Palmer Station, located along the rapidly warming West Antarctic Peninsula (WAP). First, I examined foraging behaviors of tagged Adélie and gentoo penguins while an autonomous underwater vehicle simultaneously measured Antarctic krill (penguins’ main prey) distributions. We detected krill aggregations within the horizontal and vertical foraging ranges of both species. Adélie and gentoo penguins had spatially and vertically segregated foraging habitats, a strategy that may limit competition for food. This reveals that these recently sympatric penguin species were unlikely competing for food, which agrees with recent studies showing that krill biomass is not in decline. This is a notable finding because past studies hypothesized that WAP penguin population declines are mainly driven by increased competition and decreased krill biomass, related to large-scale changes in sea ice concentration (SIC) and sea surface temperature (SST). Second, I found that interannual variability in Adélie penguin chick fledging mass was related to large-scale climate and local weather; chicks weighed less in cold, wet and windy years, suggesting there could be increased thermoregulatory costs for wet chicks. The mass of a chick before fledging the colony is thought to be an important indicator because heavier chicks are more likely to recruit into the breeding population. This direct impact of climate on chicks illustrates that climate change may affect penguins through pathways that are unrelated to sea-ice influenced food webs. I also conducted two continent-wide studies to understand spatiotemporal changes in Adélie, gentoo and chinstrap penguin breeding habitats throughout each species entire geographic range using SIC and SST from past satellite observations (1981-2010), and for Adélie penguins, I also used global climate model projections (2011–2100). During the contemporary period, predicted habitat suitability largely agreed with population trends and declining Adélie penguin populations experienced more years with warm sea surface temperature compared to populations that are increasing. An ensemble of global climate models suggests one-third of current Adélie penguin colonies may be in decline by 2060 but refugias may exist in parts of the continent beyond 2099, especially in the Ross and Amundsen Seas. I was not able to determine the mechanism relating austral-summer SST and SIC to penguins. SIC and SST may be an indicator of the quality of terrestrial nesting habitats and chick mass, through the high covariation between oceanic and atmospheric conditions, or related to the availability or quality of food resources. This dissertation demonstrates that local and large-scale studies can provide insights into species habitat use, indicators of penguin population trends and ultimately, a greater understanding of the consequences of climate change in the Southern Ocean.