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BIOL 4120: Principles of Ecology Lecture 17: Community Ecology

BIOL 4120: Principles of Ecology Lecture 17: Community Ecology. Dafeng Hui Room: Harned Hall 320 Phone: 963-5777 Email: dhui@tnstate.edu. Outline (Chapter 18) Community dynamics. 18.1 Community structure changes through time 18.2 Primary succession occurs on newly exposed substrates

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BIOL 4120: Principles of Ecology Lecture 17: Community Ecology

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  1. BIOL 4120: Principles of Ecology Lecture 17: Community Ecology Dafeng Hui Room: Harned Hall 320 Phone: 963-5777 Email: dhui@tnstate.edu

  2. Outline (Chapter 18)Community dynamics 18.1 Community structure changes through time 18.2 Primary succession occurs on newly exposed substrates 18.3 Secondary succession occurs after disturbances 18.4 Study of succession has a rich history 18.5 Succession is associated with autogenic changes 18.6 Species diversity changes during succession 18.7 Succession involves heterotrophic species 18.8 Systematic changes occur as a result of allogenic changes 18.9 Concept of community revisited

  3. 18.1 Community structure changes through time Successional changes over 30 years in a western Pennsylvania field. Cropland or Grazed grassland  grasses, goldenrod, weedy herbaceous plants  shrubs (blackberry, hawthorn) fire cherry, pine, aspen  forest of maple, oak, cherry or pine.

  4. Succession Definition: The process of gradual and seemingly directional change in the structural of the community through time fro field to forest Temporal change in community structure Sere (from the word series): sequence of communities from grass to shrub to forest historically Seral stage: a point of continuum of vegetation through time can be short or long (1 or 2 yrs to several decades) Succession happens in both terrestrial and aquatic environments

  5. William Sousa Process of succession in a rocky intertidal algal community in southern California Use concrete blocks for algae to colonize Panel b shows succession Early successional species (pioneer species): High growth rate, small size, high degree of dispersal, high rates of population growth Late successional species: Low rate of dispersal, slower growth rate, larger and live longer. Species dominance change along time

  6. Hubbard Brook Experimental Forest, New Hampshire Process of succession after forest clearing Prior to clearing, beech and sugar maple seedling dominate understory Following clearing, pin cherry, yellow birch etc.; will be replaced by of beech and maple later Primary succession (example before) and secondary succession (this example) Species dominance change along time

  7. 18.2 Primary succession occurs on newly exposed substrates Primary succession begins on sites that never have supported a community, such as rock outcrops and cliffs, sand dunes, and newly exposed glacial till. Primary succession on a coastal sand dune colonized by beach grass Later on, shrub, then trees (pines and oak)

  8. Glacier Bay fjord complex in southeastern Alaska. Ice retreats, primary succession occurs

  9. 18.2 Secondary succession occurs after disturbances Terrestrial environment: Old field succession in the Piedmont region of North Carolina by Dwight Billings in the late 1930s Abandoned farmland Decline in pine and increase in hardwood (oak and hickory)

  10. 18.3 Rich history of succession study Friderick Clements (1916, 1936): Monoclimax hypothesis view community as a highly integrated superorganism, the process of succession represents gradual and progressive development of community to ultimate or climax stage (similar as development of an individual organism) F. Egler (1954):Initial floristic composition succession at any site depends on which species gets there first. No species is competitively superior to another. Once the original dies, the site becomes available to others. Joesph Connell (1977): three models (facilitation model, inhibittion model, and tolerance model) Overall: adaptations and life history traits of individual species influence species interactions and ultimately species distribution and abundance under changing environmental condisiotns.

  11. 18.4 Succession is associated with autogenic changes in environmental conditions Environmental changes can be grouped into two classes: • Autogenic (direct result of organisms within community) • Created by community itself • Light in a forest • Allogenic (a feature of physical environment) • Created by physical environment • Elevation on a mountain • Stress in a salt marsh • Succession: changes in community structure through time; specifically, changes in species dominance) • When plant succession, it creates autogenic environmental change in a place • Both primary and secondary succession, colonization alters environmental conditions

  12. When plant succession, it creates autogenic environmental change in a place. For example, light environment (vertical distribution) • Light availability decline from canopy to ground levels • Initial colonization, the light at ground level is high, seedlings are able to establish themselves. • As plants grow, their leaves intercept sunlight, reducing light to short plants • The reduction in light enables fast-growing plants to out-compete the other species and dominate the site • Sun-adapter, share-intolerant plants exhibit high rates of photosynthesis and growth under high-light conditions. Under low light, they can not survive • Shade-tolerant species exhibit much low photosynthesis rate and growth under high-light conditions, but are able to continue photosynthesis and growth, and survival under low-light (trade-off) • In the early stage, shade-intolerant species dominate because of their high growth rate. They grow and shade the slower growing, shade-tolerant species. As time progresses and light level decline below the canopy, seedlings of the shade-intolerant species can’t grow and survive in the shaded conditions. At this time, although shade-intolerant species dominate the canopy, no new individual are being recruited. In contrast, shade-tolerant species will germinate and grow, and replace the old, dead shade-intolerant spp.

  13. Example of succession • 1st • Shade intolerant species • Eventually dominate only in canopy • 2nd • Shade tolerant species invade • Shade intolerant die out due to no seedlings • Shade tolerant take over

  14. 18.6 Species diversity change during succession In addition to shifts in species dominance, patterns of plant species diversity change over the course of succession. Comparison of species diversity at different sites within an area that are at different stages of succession Chronosequences (or chronoseres) These groups of sites For example, farmland abandoned at different times

  15. Changes in plant diversity during secondary succession of an oak-pine forest in Brookhaven, New York. Species richness increases into the late herbaceous stage, declines into the shrub stage, then increases in the early forest stages, then decreases thereafter.

  16. Normal growth rate Double growth rate Hypothetical succession involving five plant species Species diversity increases initially as new species colonize the site. As autogeneically changing environments and competition result in the displacement of early successional species, diversity declines

  17. Pattern of succession under three different disturbance frequencies Wrong? Intermediate disturbance hypothesis: community with intermediate disturbance has large species diversity

  18. 18.7 Succession involves heterotrophic species Not only autotrophic component of community (plant succession) show succession, changes in heterotrophic component of the community also occur. Decomposition Tree fall  bark beetle, wood boring beetle  fungi  bacteria  predator insects (centipedes, mites, pseudoscorpions, beetles)  fungi  moss and lichens  seedlings

  19. As plant succession advances, changes in structure and composition of the vegetation result in changes in the animals life that depends on vegetation as habitats.

  20. 18.8 Systematic changes in community structure occur as a result of allogeneic environmental change at a variety of timescales Shifting patterns of community structure in response to autogenic environmental changes often occur at time scales relating to the establishment and growth of the vegetation. Purely abiotic environmental change can produce patterns of succession over time scales ranging from days to millennia.

  21. Paleoecology: study of distribution and abundance of ancient organisms and their relationship to the environment

  22. 18.10 The concept of community revisited Two views of community: organismal view and individualistic view Reality lies somewhere in the middle Organismal community is a spatial concept: variety of plant and animal species interacting and influencing the overall structure Continuum view is a population concept, focusing on the response of the component species to the underlying features of the environment. An example (demonstrate two views)

  23. Patterns of co-occurrence for 4 plant species on a landscape along a gradient of altitude

  24. End

  25. Changes in diversity in one part of community can affect another part Greater diversity of vertical layers of forest More bird species Variation in diversity during forest succession Affects mammal species

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