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Conserving Biodiversity in the Western Antarctic Peninsula Region: Marine Protected Area Design and Policy Implications

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dc.contributor.advisor de Mutsert, Kim
dc.contributor.author Dahood-Fritz, Adrian
dc.creator Dahood-Fritz, Adrian
dc.date.accessioned 2018-10-22T01:19:54Z
dc.date.available 2018-10-22T01:19:54Z
dc.date.issued 2017
dc.identifier.uri https://hdl.handle.net/1920/11276
dc.description.abstract Well-designed marine protected areas (MPAs) help preserve biodiversity and contribute to the management of sustainable fisheries. MPAs may be particularly important in environments where sea-ice loss is rapidly increasing areas available to fisheries. The Commission for the Conservation of Antarctic Marine Living Resources (CCAMLR) has recognized that establishing MPAs could help achieve its conservation and fisheries management goals. The CCAMLR has agreed on objectives to be met by future MPAs. Two of these objectives relate to preserving ecosystem processes and functions. Antarctic MPA design processes to date have relied on static maps of biodiversity values and human use patterns to inform boundary selection. Such processes assume spatial stability of the ecosystem functions and processes that created observed patterns of distribution and abundance. This work seeks to supplement the CCAMLR MPA planning process by using dynamic food web modeling to inform MPA boundary selection. Ecopath with Ecosim is a multi-tiered dynamic food web modeling software package. It was used to develop a mass balanced food web model (Ecopath), time dynamic simulations of the food web (Ecosim), and spatially and temporally dynamic simulations (Ecospace) for the Western Antarctic Peninsula (WAP) region. Ecospace simulations were used to evaluate the impact of four MPA boundary scenarios on biomass accumulation patterns. These analyses effectively evaluated if the proposed boundaries would protect ecosystem processes that contribute to biomass accumulation. The Ecopath model was designed to include all currently monitored species as single species groups to facilitate MPA planning. The Ecosim model was successfully calibrated for the years 1996-2012 using time dynamic simulations. When sea-ice temporal dynamics were included as forcing functions, the model recreated trends in abundance for key monitored species. Ecospace simulations included spatial aspects of the sea-ice regime and adequately represented spatial trends in biomass accumulation for the years 1996-2012. 100-year scenarios were developed that examined the impact of sea-ice conditions, fishing levels, and MPA boundary configurations. Scenario evaluation illustrated the importance of fishing level in influencing spatial patterns of biomass accumulation. While MPA scenario evaluation highlighted that to be effective in the WAP an MPA must be very large, be in place for an extended period, and could consider including southern regions that may have increased importance as sea-ice loss progresses. The aim of this research is to use insights gained from spatio-temporal dynamic food web modeling to contribute to the discussion on which areas to prioritize for protection in the Western Antarctic Peninsula region.
dc.format.extent 289 pages
dc.language.iso en
dc.rights Copyright 2017 Adrian Dahood-Fritz
dc.subject Ecology en_US
dc.subject Conservation biology en_US
dc.subject Antarctica en_US
dc.subject Ecopath with Ecosim en_US
dc.subject Ecospace en_US
dc.subject Food Web Model en_US
dc.subject Marine Protected Area en_US
dc.title Conserving Biodiversity in the Western Antarctic Peninsula Region: Marine Protected Area Design and Policy Implications
dc.type Dissertation
thesis.degree.level Ph.D.
thesis.degree.discipline Environmental Science and Public Policy
thesis.degree.grantor George Mason University


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