1. Population Dynamics

2. Populations are dynamic
Size
Density
Age distribution
Dispersion (spatial pattern)
These changes (population dynamics) occur in response to environmental stress

3. Dispersion patterns within populations

4. Why clumping? Resources vary from place to place
Moving in groups allow better chance finding resources
Living in groups protects some animals from predators
Hunting in packs give some predators an advantage of finding and capturing prey
Some species form temporary groups for mating and caring for young
Raft of sea otters

5. Four variables which govern population size
Births
Immigration
Death
Emigration
Population Change = (Births + Immigration) – (Deaths + Emigration)

6. Age Structure
How fast a population grows or declines depends on its age structure.
Prereproductive age: not mature enough to reproduce.
Reproductive age: those capable of reproduction.
Postreproductive age: those too old to reproduce.
Baby hippos stay with their mother for 4 years and reach their reproductive age at about 5 – 6 years

7. What would you say about this population of fish if they are capable of reproducing between the ages of 10 and 20 years?
What would you say about this population if they did not reach reproductive age until the age of 26 years?

8. Factors affecting population size
Intrinsic rate of increase
Environmental Resistance
Carrying Capacity
Minimum Viable Population

10. Limits on population growth
No population can increase its size indefinitely.
The intrinsic rate of increase (r) is the rate at which a population would grow if it had unlimited resources.
Carrying capacity (K): the maximum population of a given species that a particular habitat can sustain indefinitely without degrading the habitat.

12. Factors affecting carrying capacity
Competition for resources
Immigration and emigration of other species
Natural and human-caused catastrophes
Seasonal fluctuations
Lake Lanier, GA in Spring 2008

13. What happens when a population exceeds its carrying capacity
Dieback (crash)
Easter Island
Cause damage – reduce area’s carrying capacity
Overgrazing by cattle
Reduces grass cover in some areas
Allows nonnative species to inhabit the area (opportunists)
Sagebrush invaded after overgrazing occurred by cattle (the cattle do not eat the sagebrush)

14. Minimum viable population
The smallest possible size at which a population can exist without extinction from natural disasters, genetic changes, human influence, or environmental factors

15. The intrinsic rate of increase falls and extinction is likely
If a population falls below minimum viable population (MVP) needed to support a breeding population:
Individuals may not be able to locate mates
Genetically related individuals may interbreed
Genetic diversity may be too low
California condor
The intrinsic rate of increase falls and extinction is likely

16. Genetic diversity can affect the size of a population
Founder effect
When only a few individuals in a population colonize a new habitat that is geographically isolated
Demographic bottleneck
When only a few individuals in a population survive a catastrophe (i.e. fire or hurricane) and this lack of genetic diversity may limit ability to rebuild population
Genetic drift
Random changes in gene frequencies where some individuals breed more than others and their genes may eventually dominate the gene pool
Inbreeding
Individuals in a small population mate with one another

17. Under some circumstances population density affects population size
Density-independent population controls
Their effect is not dependent on the density of the pop.
Floods, hurricanes, severe drought, seasonable weather, fire, habitat destruction, and pesticide spraying
Density-dependent population controls
Competition for resources, predation, parasitism, and disease

18. Density-dependent population controls
Higher density may help find mates, but can lead to increased competition for mates, food, living space, water, sunlight, and other resources

19. Density-dependent population controls
Can help shield members from predators, but it can also make large groups such as schools of fish vulnerable to human harvesting methods

20. Density-dependent population controls
Close contact among individuals in a dense population can increase the transmission of parasites and infectious disease
April 2010: Connecticut deer population is 64 deer/ square mile – the deer population’s density is contributing to the spread of Lyme disease to humans (they would like to get the deer population down to 12 deer/ square mile

21. Several different types of population change occur in nature
Population sizes may stay the same, increase, decrease, vary in regular cycles, or change erratically.
Stable: fluctuates slightly above and below carrying capacity.
Irruptive: populations explode and then crash to a more stable level.
Cyclic: populations fluctuate and regular cyclic or boom-and-bust cycles.
Irregular: erratic changes possibly due to chaos or drastic change.

23. Cyclic fluctuations (boom-and-bust cycles)

24. Top-down population control
Predators (high on trophic pyramid) regulate prey population size
Example of top-down effects
Increase in number of predators
Reduces size of herbivore population
Increases size of plant population
Reduces nutrients in soil

25. Bottom-up population control
Each trophic level derives its energy from the level below it
Productivity of the species on the lower layer sets the bounds on the population sizes of the species on the higher layer
Example of bottom-up effects
Increase nutrients in soil
More nutrients increases size of plant population
More plants increases herbivore population
More herbivores increases size of predator population

26. Lynx-Hare Population Cycle
Is it top-down or bottom-up?

27. How does productivity influence top-down or bottom-up population control?
With high primary productivity
Higher primary productivity results in herbivore populations large enough to support prey populations
Predators suppress the herbivore populations = top-down regulation
With low primary productivity
When primary productivity is low, there is not enough production of biomass to sustain large herbivore populations = bottom-up regulation

28. Reproductive Patterns

29. Survivorship Curves
K-selected species
r-selected species