1. Introduction – Landscape Ecology Landscape Ecology: Study of landscape structure and processes. –Landscape: Heterogeneous area composed of several ecosystems. –Landscape Elements: Visually distinctive patches in an ecosystem.

2. Vancouver Island marmot (Marmota vancouverensis) Isolated from hoary and Olympic marmots ~100 left

3. Vancouver Island marmot (Marmota vancouverensis) Natural tree succession

4. Vancouver Island marmot (Marmota vancouverensis) Logging – disjunct patches - max. dispersal = 7 km Climate Prey-Predator Dynamics

5. Human Land Use Practices 1)Agriculture 2)Suburban Development Let’s pick on Indiana: 97% of land in state = privately- owned In central Indiana, 70+% of land in row crop <10% in forest Urban sprawl intensifying

6. Human Impacts Ecosystem simplification: elimination of species from food webs via human alterations to land Example: vertebrate communities in ag. landscapes

8. Intensive Agriculture & Clean Farming

9. Timber Extraction & Fragmentation

10. Formation of Terrestrial “Islands”

11. Habitat Fragmentation Process of breaking contiguous unit into smaller pieces; area & distance components Leads to: < remnant patch size > edge:interior ratios > patch isolation < connectivity Community & Ecosystem processes altered

12. Formation of Terrestrial “Islands”

14. Habitat Loss vs. Habitat Fragmentation

15. #patches Patch isolation Patch size Edge

17. What about aquatic systems?

18. What about aquatic systems? Con.Bio 12(6)

19. Habitat Fragmentation area-sensitive species: species that require minimum patch size for daily life requirements Edge effects: influence of factors from outside of a patch

20. Increased Edge Habitat

22. Edge Effects Habitat surrounding a patch can: -change abiotic conditions; e.g., temp. -change biotic interactions, e.g., predation Example of nest predation = edge effect of approximately 50 m into forest patch

23. Habitat Fragmentation First-Order Effects: fragmentation leads to change in a species’ abundance and/or distribution

24. Habitat Fragmentation Higher-Order Effects: fragmentation indirectly leads to change in a species abundance and/or distribution via altered species interactions

25. Predators - Abundance - Distribution - Foraging Behaviors Avian Competitors Avian Prey Brood Parasites HABITAT FRAGMENTATION Ground- Nesting Birds - Abundance - Distribution Parasites - Abundance - Distribution REPRODUCTIVE SUCCESS + – –– + +

26. Habitat Fragmentation: Species- Specific Sensitivity? Rare species = more vulnerable Wide ranging species = large-area requirements Species with reduced mobility = more vulnerable Species with low fecundity (related to rarity?) Species with short life cycle (or multi- stage life cycle?)

27. Habitat Fragmentation: Species- Specific Sensitivity? Ground-nesting birds may be more vulnerable (30-60% reduction in last 25 yrs) Interior-dependent species Species vulnerable to human exploitation or disturbance Specialist species?

28. Habitat Fragmentation: Species- Specific Sensitivity? Generalizations are a good start (= hypotheses?), but a little more complex than that……

29. Gehring and Swihart. 2003. Biological Conservation 109:283-295

30. Spatial and Temporal Ecology of Raccoons Gehring et al. In prep.

31. Swihart et al. 2003. Diversity and Distributions 9:1-8.

32. Brown and Litvaitis. 1995. Canadian Journal of Zoology 73:1005-1011

33. Implications of Changes in Scale Insects sampled at 10-m intervals for 100 m

34. Implications of Changes in Scale Insects sampled at 2000-m intervals for 20,000 m

35. Landscape Pattern I.Landscape Components (attributes of features or spatial elements) A.Composition B.Configuration C.Connectivity Relative to landscape spatial elements….

36. How much of the area is comprised of each type of spatial element? How are spatial elements arranged in space? How do these attributes change through time?

37. How does one quantify landscape pattern? How do biotic communities interact with pattern?

38. Causes of Landscape Pattern I.Abiotic Factors II.Biotic Factors III.Human Landuse IV.Disturbance & Succession

39. Causes of Landscape Pattern Abiotic Factors –Variance in climate (biogeographic influences) –Variance in landform (more localized constraints; microclimates)

41. Common N.A. trees – contractions & radiations in distribution

42. Influence of landform – spatial pattern of species distribution

43. Causes of Landscape Pattern Biotic Factors –Competition –Predation

44. Causes of Landscape Pattern Human Land Use –Prehistoric, Historic, Present Effects Shift from nomadic hunter-gatherer to farming systems

45. Human Land Use Practices 1)Agriculture 2)Suburban Development *Landuse / Landcover Data from USGS sources (typically resolution to 30 m)

46. Causes of Landscape Pattern Human Land Use –Present Effects Extraction of natural resources Patterns of development Transportation networks

47. Roads: Formation of Barriers in Landscapes

48. Clearcuts and National Forest Management

49. Patch Clearcuts

50. Landscape Processes Landscape structure influences processes such as the flow of energy, materials, and species between the ecosystem within a landscape.

51. Landscape Structure and Dispersal of Small Mammals

52. Habitat Patch Size and Isolation and Density of Butterfly Populations

53. Organisms and Landscape Structure African elephants knock down tress. –Change woodland to grassland. Kangaroo Rats dig burrow systems that modify soil structure and plant distributions. Beavers cut trees, build dams and flood surrounding landscape. –At one time, beavers modified nearly all temperate stream valleys in Northern Hemisphere.

54. Organisms and Landscape Structure Johnston and Naiman documented substantial effects of beavers on landscape structure. –Over 63 yrs, area created by beavers increased from 200 ha to 2,661 ha. –Changed boreal forest landscape to complex mosaic.

55. Organisms and Landscape Structure Beaver activity between 1927-1988 increased quantity of most major ions and nutrients in impounded areas. Three possible explanations: –Impounded areas may trap materials. –Rising waters captured nutrients formally held in vegetation. –Habitats created by beavers may promote nutrient retention by altering biogeochemical processes.

56. Introduction – Geographical Ecology MacArthur defined geographical ecology as the search for patterns of plant and animal life that can be put on a map. –Above level of landscape ecology. –Vast breadth Chapter only focuses on a few aspects.

57. Oceanic Island = Terrestrial Island ?????

58. Island Area and Species Richness Preston found fewest bird species live on smallest islands and most species on largest islands. Nilsson et.al. found island area was best single predictor of species richness among woody plants, carabid beetles, and land snails.

59. Island Area and Species Richness

60. Species-Area Relationship S = cA z S = # of species A = island area Positive correlation between island size & number of species Applies to terrestrial “islands” also

62. Habitat Patches on Continents: Mountain Islands As Pleistocene ended and climate warmed, forest and alpine habitats contracted to the tops of high mountains across American Southwest. –Woodlands, grasslands, and desert scrub, invaded lower elevations. –Once continuous forest converted to series of island-like fragments associated with mountains: Montane.

63. Lakes as Islands Lakes can be considered as habitat islands. –Differ widely by degree of isolation. Tonn and Magnuson found the number of species increases with the area of an insular environment. Barbour and Brown found positive relationship between area and fish species richness.

64. Lakes as Islands

65. Marine Islands MacArthur and Wilson found isolation reduces bird diversity on Pacific Islands. Williamson summarized data from relationship between island area and species richness in Azore Islands: –Birds show clear influence of isolation on diversity, ferns do not. –Land birds fly across water barriers, and ferns produce large quantities of light spores easily dispersed in the wind.

66. Marine Islands

67. Isolation and Habitat Islands on Continents Lomolino et.al. found a strong negative relationship between isolation and the number of montane mammal species living on mountaintops across the American Southwest.

68. Equilibrium Model of Island Biogeography MacArthur and Wilson: Model explaining patterns of species diversity on islands as result of immigration and extinction rates. –Reasoned rates of immigration would be highest on new island with no organisms. As species began to accumulate, rate of immigration would decline since fewer arrivals would be new species.

70. Equilibrium Model of Island Biogeography Predicted rate of extinction would rise with increasing number of species on an island for three reasons: –Presence of more species creates a larger pool of potential extinctions. –As number of species increases, population size of each must diminish. –As number of species increases, potential for competitive interactions between species will increase.

71. Equilibrium Model of Island Biogeography Point where two lines cross predicts the number of species that will occur on an island. Proposed rates of extinction on islands would be determined mainly by island size. –LG near islands will support highest number. –SM far islands will support lowest number. –SM near and LG far will support intermediate number.

72. Island Biogeography equilibrium model suggesting that the number of species occurring on an island represents a balance between immigration (in) and extinction (out) Robert MacArthur & E.O. Wilson

75. Experimental Island Biogeography Simberloff and Wilson studied insect recolonization in Florida Keys. –Chose 2 stands of mangroves as control islands, and 6 others as experimental islands. Defaunated islands –Followed recolonization for 1 yr. »Species number stayed constant, but composition changed considerably.

76. Experimental Island Biogeography

77. Colonization of New Islands by Plants Rydin and Borgegard found variation in spp. richness correlated positively with island area and accounted for 44-85% of variation in species richness among islands. –Small and medium islands continued to accumulate species. –Large islands attained equilibrium of immigration and extinction. Difficult to separate effects of habitat diversity from area effects.

78. Manipulating Island Area Simberloff tested effect of island area on species richness. –In all cases where area was reduced, species richness decreased. Richness on control island increased slightly. –Islands with reduced area lost species with each reduction in area. Showed area has positive influence on species richness.

79. Manipulating Island Area

80. Island Biogeography Update Brown and Kodric-Brown found higher immigration rates to near islands can reduce extinction rates. Lomolino found island area can have a significant effect on immigration rates. Area and isolation are only two of several environmental factors affect island species richness.

81. Latitudinal Gradients in Species Richness Most groups of organisms are more species-rich in the tropics. Brown grouped hypotheses into six categories: –Time Since Perturbation More species in the tropics because tropics are older and disturbed less frequently. –More time for speciation, and less frequent disturbance reduces extinction rate.

82. Latitudinal Gradients in Species Richness –Productivity High productivity contributes to high species richness. –More energy to divide among population. –Environmental Heterogeneity More heterogeneity, thus more potential habitat areas and niches.

83. Latitudinal Gradients in Species Richness –Favorableness Tropics have more favorable environments. –No extremes to limit diversity. –Niche Breadth and Interspecific Interactions Various themes –Brown suggests biological processes must play secondary role. »Ultimate causes must by physical differences.

84. Area and Latitudinal Gradients in Species Richness Rosenzweig proposed immigration can be largely discounted at broad scales, thus speciation will be primary source of new species. –Species removal via extinction. Tropics richness is greater due to higher rates of speciation and / or lower rates of extinction.

85. Continental Area and Species Richness Rosenzweig found a strong positive relationship between area and species diversity.