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Population and community-level consequences of fragmentation

Population and community-level consequences of fragmentation. interrupts ecological patterns and processes reduced habitat patch area edge effect increased patch isolation decreased successful movement (immigration and emigration) increased likelihood of local extinction.

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Population and community-level consequences of fragmentation

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  1. Population and community-level consequences of fragmentation • interrupts ecological patterns and processes • reduced habitat patch area • edge effect • increased patch isolation • decreased successful movement (immigration and emigration) • increased likelihood of local extinction

  2. Processes operating between fragments • dispersal • increasing fragmentation decreasing colonization rates • leads to decreasing # of species within patch • increasing risk of local extinction of species within patch

  3. Processes operating between fragments • dispersal • matrix • disturbed/converted habitat surrounding fragments • potential roles? matrix

  4. Persistence of populations • In which directions would you predict net movement of individuals? • Which populations are more likely to persist? why? Disappear? • What are the factors most important in determining a population’s likelihood to persist? • Which populations, if they disappear, are most likely to be recolonized?

  5. Grizzly bear • 50,000 historic estimate • Persecution and habitat changes == about 1,200 wild grizzlies remain in lower 48

  6. Grizzly bear ecosystems 40-50 30-40 ? http://www.fws.gov/mountain-prairie/species/mammals/grizzly/ <20 >500 0?

  7. Y2YYukon to Yellowstone Conservation Initiative • Goal: maintain and sustain region to allow wilderness, wildlife, native plants, and natural processes to function as an interconnected web of life • Partnerships of NGOs, businesses, foundations, concerned citizens, scientists • Based on science • Balance area needs

  8. Cascade Land Conservancy In conjunction with members of communities, work toward large-scale conservation • Habitat Lands • Farmland • Working Forests • Parks, Trails and Open Spaces • Shorelines and Estuaries

  9. Natural Landscapes are also heterogeneousWhy?

  10. Natural Landscapes are also heterogeneousWhy?Topography and climate

  11. How Rain Shadows Form wet W sides, dry E sides Rainshadows Air mass Cascades Olympics Pacific Ocean Puget Trough Ellensburg Ppt 10-12” Ppt 100-200” Ppt 10-12” North Bend Seattle Ppt 36” Ppt 100”

  12. Generalized Forest Zones of the Washington Cascades Cross-section of Cascades WEST EAST Alpine Alpine Spruce-fir Mountain hemlock Douglas-fir Pacific silver fir Ponderosa pine Western hemlock Shrub-steppe

  13. Natural succession Structural diagram for successional seres in Douglas-fir forests (Franklin and Spies 1991)

  14. Natural succession Structural diagram for successional seres in Douglas-fir forests (Franklin and Spies 1991) Succession from different sources of disturbance: fire, cutting

  15. Natural Disturbances • Disturbance: an event that causes a change to resource availability, substrate, or the physical environment • Fire, wind storm, insect outbreak, floods • Disturbance regime: spatial and temporal dynamics of disturbances over a longer time period • Defined by frequency, intensity, severity, size

  16. Regional & landscape scale patterns of forest disturbance from Turner, et al (2001) Turner et al. 2001

  17. Patch Dynamics: over space and time, disturbances create a mosaic of patches of various sizes, shapes, and successional stages across an area from Turner, et al (2001)

  18. Role of Fire • Habitat diversity: • landscape mosaics • uneven-aged stands (in most cases) • dead and dying trees • Nutrient release • Leads to a greater diversity of wildlife

  19. Landscape mosaic created by the 1988 Yellowstone fires

  20. Ecological Legacies • Remain after disturbance • Influence ecological effects of disturbance and patterns of succession • Snags, logs, roots, seeds Scrub Oak: Survive fires only by resprouting

  21. Wildlife Responses to Fire

  22. Serotinous Cones • Sealed by resin • Opened by fire • A new generation grows (ex Jack Pine)

  23. Winners and Losers • Disturbances change habitat naturally • Some wildlife increase = “winners” • Some wildlife decrease = “losers” • Some generalists show little change • Disturbance is not “good” or “bad” for all wildlife

  24. How Did Fire Affect PNW Forests? Historical Fire Regimes • HighSeverity • Infrequent (100+ yrs) and stand-replacing • MixedSeverity • Less frequent (25-75 yrs) and a mix of severities • LowSeverity • Frequent (5-15 yrs) but low intensity

  25. Fire improves browse quality • Stimulates new growth • Higher protein • Higher digestibility • Attracts moose, elk, deer, and their predators (wolves) plus bears

  26. Pyrophilic Insects • Barbeque Beetle • Infrared sensors on abdomen to detect fire from a distance • With predators and sticky tree resin gone after fire, good conditions for mating • Xenomelanophila miranda beetle • Mate on charred trees soon after fire

  27. Black-backed Woodpecker • Nearly restricted in its habitat distribution to standing dead forests created by stand-replacement fires • Feed on larvae of the black fire beetle

  28. Longleaf Pine of the Southeast • Fire-dependent ecosystems • Historically, surface fires every 3-5 years • Ignited by lightning and Native Americans • Now maintained by prescribed burning

  29. Red-cockaded Woodpecker • Endangered (SE) • Requires large, live longleaf pine trees • Longleaf is a fire-adapted species

  30. Lives in large LIVE longleaf pine • Drills holes around the cavity • Resin flows – defense against snakes • Longleaf pine type one of most endangered forest types in world – 99% gone

  31. Prescribed burning used to maintain Longleaf Pine savannaThere is no ecological equivalent to fire

  32. Kirtland’s Warbler • Endangered species • In danger of extinction until an out-of-control fire triggered a population revival • Nests in young Jack Pine, a fire-dependent species with serotinous cones

  33. Wildlife Management • Stand-replacement fires may be necessary for long-term maintenance of many pyrophilic wildlife populations • Such fires are controversial due to human safety

  34. Wildlife Management • Salvage cutting may reduce the suitability of burned-forest habitat by removing the most important element-standing: fire-killed trees needed for foraging and nesting (ecological legacies) • Prescribed burning becoming more accepted as a tool to reduce fuel loads

  35. Landscape Alterations Can Profoundly Affect Natural Ecological Systems High Urbanization Effect of Fragmentation Persistence of Change Agriculture High Low Timber Harvest Low Low High Similarity of Alteration to Natural Habitat

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