Chapter 13 Author: Lee Hannah. FIGURE 13.1 Species ’ Range Shift and Protected Area. This figure from Peters ’ seminal early work on climate change and.

Slides:

Advertisements

Similar presentations

The Effects of Climate Change on Biological Diversity

Advertisements

Towards a framework for integrated conservation planning of coastal catchments and nearshore marine areas.

Coral reefs: apex predator paradise or mesopredator nirvana? MR Heupel, DM Knip, CA Simpfendorfer, NK Dulvy.

Impacts in the Southeast Challenges to Everglades Restoration Everglades has shrunk due to human manipulation of the region’s water; ongoing efforts aim.

Chapter 11 Author: Lee Hannah. FIGURE 11.1 Schematic of an SDM. Species distribution modeling begins with selection of a study area (left). The study.

Impacts of Climate Change on Coral reefs in the Caribbean Mrs. Marcia Creary.

Climate Change Impacts in the United States Third National Climate Assessment [Name] [Date] Hawai’i & Pacific Islands.

Caring for The Great Barrier Reef Marine Park & World Heritage Area Dr Laurence McCook, Great Barrier Reef Marine Park Authority, Pew Fellow in Marine.

Managing Marine Conservation Zones Dr Angela Moffat Marine Bill Project Manager Natural England

Climate change and tropical coastal ecosystems

JJM Intergovernmental Panel on Climate Change 2001 Under the auspices of the World Meteorological Organization and the United Nations Environmental Program.

The Mesoamerican Barrier Reef

Climate Change and its impact on Forests in Europe and North America Andrew J. R. Gillespie, Ph. D. United States Environmental Protection Agency.

Environmental Threats to the Great Barrier Reef Allison Botkin.

Effects of Climate Change on Marine Ecosystems David Mountain US CLIVAR Science Symposium 14 July 2008.

Physical Geography SS6G12, SS6G13

Australia Physical Geography.

Climate Change Impacts in the United States Third National Climate Assessment [Name] [Date] Great Plains.

Ecosystem Based Approach to Management and Ocean Observing Kevin Friedland National Marine Fisheries Service, 28 Tarzwell Dr., Narragansett, RI 02882,

Climate change, ecological impacts and managing biodiversity Mark W. Schwartz

Chapter 09 Author: Lee Hannah. FIGURE 9.1 Timeline of Extinction Events. Major extinctions are indicated by yellow bars. Along with climate change, impacts.

Chapter 04 Author: Lee Hannah. FIGURE 4.1 Accelerating Ice Break up and Delayed Ice Formation. Ice break up and formation is shown for major rivers and.

“Oceans, Coasts, and Fisheries”

The Mesoamerican Reef. Introduction  Also Known as The Mesoamerican Barrier Reef System  Abbreviated to MAR  Second largest in the world  Largest.

Biomass Biodiversity is greatest in the tropics Biodiversity is generally greatest in the southern hemisphere Seventy per cent of the world's species.

Biodiversity. What is Biodiversity? Biological Diversity –Number and variety of species in a given area Complex relationships difficult to study –Often.

© 2014 Pearson Education, Inc. Chapter 15 Animals of the Benthic Environment Rocky and sandy shores Coral Reef Deep Sea.

Habitat Destruction: Loss of Coral Reefs CRISTINA OVALLE INTRO. TO BIOLOGY II BIOLOGY 1312 UNIVERSITY OF HOUSTON-DOWNTOWN.

Chapter 4 Ecosystems and Communities. Copyright Pearson Prentice Hall 4-1 The Role of Climate.

Modelling alien invasives using the GARP system Some thoughts to bear in mind. James J. Reeler Department of Biodiversity and Conservation Biology University.

Marine Protected Areas in South Africa: from coastal successes to offshore challenges Colin G. Attwood Marine Research Institute University of Cape Town.

REEF AT RISK Finding the Resilience Area Izarenah, M.R., Hyde, J., Alvin, J.C., Sue, C.Y., and Chan,A.A.

THE GREAT BARRIER REEF THE GREAT BARRIER REEF (homereading

Changing Structures and Densities of Symbiotic Dinoflagellates in Reef Systems By: Mara Potthoff.

Comments on the Marine Spatial Planning Bill

Impacts of Global Climate Change on Central African Ecosystems

Coral Reefs and Climate Change

Lee Hannah Conservation International

Essential Biodiversity Variables: towards an agreement on a common approach for biodiversity Rob Jongman, Wageningen UR Henrique Pereira, University of.

Coral Reef solid structures built from the remains and deposits of marine organisms called polyps (most the size of your fingernail) organisms secrete.

CH15: Connectivity and Landscape

CH16: Species Management

CH09: Extinctions.

CH07: Past Marine Ecosystem Changes

CH14: Adaptation of Conservation Strategies

Ocean acidification & Ocean warming

CH03: Species Range Shifts

HUMAN HEALTH THE IMPACTS OF CLIMATE CHANGE ON IN THE UNITED STATES:

CH14: Adaptation of Conservation Strategies

CH03: Species Range Shifts

CH11: Modeling Species and Ecosystem

CH07: Past Marine Ecosystem Changes

CH15: Connectivity and Landscape

Biodiversity….THINK ABOUT IT

CH09: Extinctions.

Reasons to Conserve Nature

CH11: Modeling Species and Ecosystem

CH13: Ecosystem Services

by Tracy D. Ainsworth, Scott F. Heron, Juan Carlos Ortiz, Peter J

Examples of AEGIS autonomous target selection.

Environmental and evolutionary controls on Triassic reef recovery

Projected changes to coral reefs and mangroves

Ecosystem-Based Fisheries Management

CH16: Species Management

Examples of AEGIS autonomous target selection.

by Tracy D. Ainsworth, Scott F. Heron, Juan Carlos Ortiz, Peter J

A Quantification of Risk Factors on Oceanic Sharks

Fig. 1 Global primate species richness, distributions, and the percentage of species threatened and with declining populations. Global primate species.

Fig. 5 Schematics illustrating enhancement in April tornado activity due to SST. Schematics illustrating enhancement in April tornado activity due to SST.

Presentation transcript:

Chapter 13 Author: Lee Hannah

FIGURE 13.1 Species ’ Range Shift and Protected Area. This figure from Peters ’ seminal early work on climate change and biological diversity shows the changing relationship between a species ’ range and a protected area. The species ’ range is indicated by hatching. As climate shifts, the proportion of range within the protected area changes. The figure shows the reserve being lost as the species ’ range ceases to intersect with it, but it is unlikely that a reserve would be declassified based on the loss of only one species. The reserve would remain important for many other species, so the greater question is how to maintain protection of the species that has moved beyond the reserve. Adding a protected area within the new range of the species is one important option. Reproduced with permission from Yale University Press.

FIGURE 13.2 Metapopulation Range Shift with Respect to a Protected Area. A more sophisticated view of a species ’ range shift considers the area of occupancy within the species ’ range, or the individual populations that make up the overall metapopulation of the species. Range shifts in this view involve loss or change in size of individual populations, which in turn change the representation of the species in a protected area.

FIGURE 13.3 Range Shifts Relative to Multiple Protected Areas. Range shifts in three species (a, b, c) are illustrated, each relative to two protected areas. This example illustrates the complexity of conserving multiple species as ranges shift. Figure courtesy of Conservation International.

FIGURE 13.4 Diversity of Movement within a Range Shift. Assumptions that species will always shift poleward with warming are belied by modeling results. Here, the simulated range of a protea species in the Cape Floristic Region shifts away from the pole (northward). There is no poleward landmass in this region, so this species is tracking climate upslope, moving into hills above the Cape lowlands. Blue represents newly suitable future range, red represents current climatically suitable range lost, and green represents currently suitable climatic range retained. From Hannah, L., et al The view from the cape. Extinction risk, protected areas, and climate change. Bioscience 55, 231 – 242.

FIGURE 13.5 The King Protea ( Protea cynaroides ). The king protea is one of hundreds of protea species whose future ranges have been projected in species distribution modeling for the Cape Floristic Region. It is the national fl ower of South Africa. From Wikimedia Commons.

FIGURE 13.6 High Irreplaceability Areas — Alliance for Zero Extinction Sites. Alliance for Zero Extinction sites contain one or more species that occur only in those locations. These sites are irreplaceable: They must be conserved if species losses are to be avoided. Copyright National Academy of Sciences, U.S.A.

FIGURE 13.7 Healthy (Top) and Bleached (Bottom) Coral Reefs. Courtesy U.S. National Oceanic and Atmospheric Administration (NOAA).

FIGURE 13.8 Zoning Map for the Great Barrier Reef Marine Park. The Great Barrier Reef Marine Park is a marine protected area that has experienced extensive coral bleaching. In response to bleaching events and other management issues, a zoning plan for the park reflects permitted uses that best integrate climate change with other park management objectives. Tourism is excluded in some areas to facilitate postbleaching recovery. Map courtesy of the Spatial Data Centre, Great Barrier Reef Marine Park Authority, 2010.

FIGURE 13.9 Sedimentation and Shading Effects on Coral Bleaching. Shading (a) and sedimentation (b) are two factors that can infl uence the severity of coral bleaching. Sedimentation stresses corals and may exacerbate bleaching effects, whereas shading protects corals from synergies of high temperatures and photic effects, thereby reducing the probability of bleaching. Reproduced with permission from IUCN.

FIGURE Marine Protected Areas. Healthy marine systems such as these can be one of the major benefits of marine protected areas (MPAs). MPAs can improve food web health and reduce chances of coral bleaching by decreasing synergistic pressures such as fi shing and tourism overuse. Courtesy U.S. National Oceanic and Atmospheric Administration (NOAA).