1. Environmental Science: Toward a Sustainable Future �Richard T. Wright Ecosystems: How They Change
PPT by Clark E. Adams
2. Factors That Contribute to Ecosystem Change Dynamics of natural populations
Mechanisms of population equilibrium
Mechanisms of species adaptation
Ecosystem response to disturbance
Lessons to learn
3. Dynamics of Natural Populations Population growth curves
Biotic potential versus environmental resistance
Density dependence and critical number
4. Biotic Potential and Environmental Resistance
5. Population Equilibrium Births
6. Population Growth Curves
7. Population Growth Curves Reproductive strategies:
8. Population Dynamics Environmental resistance: combination of biotic and abiotic factors that may limit population increase
Predators, competitors, disease
Adverse weather, limited food/nutrients
9. Biotic Potential and Environmental Resistance
10. Density Dependence and Critical Numbers Factors of environmental resistance are either:
density-independent: effect does not vary with population density; e.g., adverse weather
density-dependent: effect varies with population density; e.g., infectious disease
Critical number: the lowest population level for survival and recovery
11. Mechanisms of Population Equilibrium Predator–prey dynamics
Competition
Interspecific
Intraspecific
Introduced species
12. Predator–Prey Balance: Wolves and Moose
13. Lessons to Be Learned about Predator–Prey Balance Absence of natural enemies allows a herbivore population to exceed carrying capacity, which results in overgrazing of the habitat.
The herbivore population subsequently crashes.
The size of the herbivore population is maintained so that overgrazing or other overuse does not occur.
14. Plant–Herbivore Dynamics No regulatory control (predation) on herbivores
Went into exponential growth pattern
Overgrazed habitat
Massive die-off of herbivores
15. Mechanisms of Population Equilibrium: Plant–Herbivore Compare the predator–prey with plant–herbivore methods of controlling the size of the herbivore population.
How would the herbivore population growth curve look if diseases or predators were used as the control mechanism?
16. Keystone Species A single species that maintains biotic structure of the ecosystem
Pisaster ochraceus: a starfish that feeds on mussels, keeping them from blanketing the rocks
17. Competition: Intraspecific Territoriality: defense of a resource against individuals of the same species
Examples of wolves and songbirds
Results in priority access and use of resources
How do wolves and songbirds establish territory?
18. Competition: Interspecific Grasslands contain plants with both fibrous roots and taproots
Coexist by accessing resources from different soil levels
19. Introduced Species Rabbits in Australia (next slide)
Chestnut blight in United States
Japanese beetles, fire ants, gypsy moths in United States
Water hyacinth, kudzu, spotted knapweed, purple loosestrife (see Fig. 4-13 in text) in United States
20. Rabbits Overgrazing in Australia
21. Introduced Species Why have introductions of nonnative and exotic species resulted in a degradation of ecosystems? (Think in terms of environmental resistance and biotic potential.)
An example of the answer to this question is given in the next slide.
22. Introduced Species: Rabbits in Australia Introduced into Australia from England in 1859
No natural enemies – rabbit population exploded
Overabundant herbivore population devastated natural vegetation (see Fig. 4-11 in text).
Using disease as control measure – why will this procedure fail in the long term?
23. Mechanisms of Species Adaptation Change through natural selection
Selective pressure determines which organisms survive and reproduce and which are eliminated.
24. Recipe for Change
25. Adaptations to the Environment
26. The Limits of Change Adapt
Move (migrate)
Die (extinction)
28. Prerequisites for Speciation Original population must separate into smaller populations that do not interbreed with one another.
List some ways this might happen.
Separated populations must be exposed to different selective pressures.
Example: arctic and gray fox (next slide)
29. Speciation: Foxes
30. Speciation: Galápagos Finches
31. Ecosystem Responses to Disturbance Ecological succession
Disturbance and resilience
Evolving ecosystems
32. Equilibrium Theory Ecosystems are stable environments in which the biotic interactions among species determine the structure of the communities present.
33. Succession and Disturbance Ecological succession: transition between biotic communities
Primary: no previous biotic community
Secondary: previously occupied by a community
Aquatic: transition from pond or lake to terrestrial community
34. Primary Succession
35. Primary Succession Mosses invade an area and provide a place for soil to accumulate.
Larger plants germinate in the new soil layer, resulting in additional soil formation.
Eventually shrubs and trees will invade the area.
36. Secondary Succession
37. Aquatic Succession
38. Disturbance and Resilience Removes organisms
Reduces populations
Creates opportunities for other species to colonize
39. Fire and Succession
40. Ground Fire
41. Fire and Succession Fire climax ecosystems: dependent upon fire for maintenance of existing balance; e.g., grasslands, pine and redwood forests
What significance does this have for humans and where they live?
42. Resilience in Ecosystems
43. Resilience Mechanisms after a Forest Fire Nutrient release to soil
Regrowth by remnant roots and seeds
Invasions from neighboring ecosystems
Rapid restoration of energy flow and nutrient cycling
44. Lessons to Learn Managing ecosystems
The pressure of population
45. Managing Ecosystems Protecting and managing the natural environment to maintain the goods and services vital to human economy and survival.
46. The Pressures of Population What is the carrying capacity for the human population on Earth?
How will the human ecological footprint impact on nature’s goods and services?
47. Carrying Capacity and Overshoot
48. End of Chapter 4
