Browsing by Subject "Borneo"
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Item Open Access Using metapopulation theory for practical conservation of mangrove endemic birds.(Conservation biology : the journal of the Society for Conservation Biology, 2020-02) Huang, Ryan; Pimm, Stuart L; Giri, ChandraAs 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 landscape features with species-specific information to produce direct information on population extinction risks. This approach contrasts with descriptions of habitat fragments, which provide only indirect information on risk. Combining a spatially explicit metapopulation model with empirical data on endemic species' ranges and maps of habitat cover, we calculated the metapopulation capacity-a measure of a landscape's ability to sustain a metapopulation. Mangroves provide an ideal model landscape because they are of conservation concern and their patch boundaries are easily delineated. For 2000-20015, we calculated global metapopulation capacity for 99 metapopulations of 32 different bird species endemic to mangroves. Northern Australia and Southeast Asia had the highest richness of mangrove endemic birds. The Caribbean, Pacific coast of Central America, Madagascar, Borneo, and isolated patches in Southeast Asia in Myanmar and Malaysia had the highest metapopulation losses. Regions with the highest loss of habitat area were not necessarily those with the highest loss of metapopulation capacity. Often, it was not a matter of how much, but how the habitat was lost. Our method can be used by managers to evaluate and prioritize a landscape for metapopulation persistence.Item Open Access Using the Ecosystem Service Value of Habitat Areas for Wildlife Conservation: Implications of Carbon-Rich Peatswamp Forests for the Bornean Orang-utan, Pongo Pygmaeus(2010-04-30T16:05:59Z) Cattau, MeganFragmentation of lowland peatswamp forests in Borneo poses a serious threat to the endangered Bornean orang-utan, whose decreasing population trends are attributed primarily to habitat loss. The orang-utan is projected to be extinct by 2020 unless existing populations can be connected and new conservation areas established, which is not currently economically viable. However, peatswamp forests, on which orang-utans can be found at their greatest densities, have a large capacity for carbon sequestration and storage and, thus, a high potential value on the carbon market. Unfortunately, as these wetlands are being deforested, drained, and burned for development, the peat soil is decomposing, emitting CO2, and impacting global climate change. This project is a spatially explicit analysis of an area of fragmented peatswamp forest in Central Kalimantan, Indonesia that explores how the conservation targets of ape preservation and carbon sequestration and storage can be mutually satisfied through land management strategies. First, I prioritized intact peatswamp forest patches for conservation based on orang-utan presence and patch geometry metrics. To do this, I surveyed line transects in the study area, Block C of the Former Mega Rice Project, for orang-utan sleeping nests and produced a regional density estimate of 2.517 individuals / km2. I identified patches greater than 350 ha from Landsat 7 TM data and then calculated the number of individuals and patch geometry metrics for each patch. I found the total population on Block C to be 2,161 individuals, only 1,146 of which are located in forest fragments with a population size large enough to be considered viable. I generated a model of habitat suitability for the orang-utan using maximum entropy methods. Then, I proposed corridors through degraded areas between the six priority patches of intact forest using least-cost path methods. The corridors included areas of high habitat suitability and also areas of high carbon value, and would increase the viable population size of orang-utans to 1,788 individuals. This project demonstrates how the incentive of carbon financing can make possible wildlife protection strategies, and how we might begin to use spatial planning to maximize biodiversity and ecosystem service benefits on the landscape.