1. Ch. 53 Warm-Up 1.(Review) Sketch an exponential population growth curve and a logistic population growth curve. 2.What is an ecological footprint? 3.What are ways that you can reduce your ecological footprint? Define:  Demography  Semelparity  Iteroparity  Carrying capacity  Exponential growth curve  Logistic growth curve  K-selection  r-selection  Ecological footprint

2. POPULATION ECOLOGY Chapter 53

3. You Must Know: How density, dispersion, and demographics can describe a population. The differences between exponential and logistic models of population growth. How density-dependent and density-independent factors can control population growth.

4. Population = group of individuals of a single species living in same general area Density: # individuals / area Dispersion: pattern of spacing between individuals Introduction

5. Determining population size and density: Count every individual Random sampling Mark-recapture method

6. Patterns of Dispersal: 1.Clumped – most common; near required resource 2.Uniform – usually antagonistic interactions 3.Random – not common in nature

7. Additions occur through birth, and subtractions occur through death. Life table : age-specific summary of the survival pattern of a population Represent data with a survivorship curve. Plot # of individuals in a cohort still alive at each age. Demography: the study of vital statistics that affect population size

8. Life Table

9. Survivorship Curves: Type I curve: low death rate early in life (humans) Type II curve: constant death rate over lifespan (squirrels) Type III curve: high death rate early in life (oysters)

10. 3 Variables: 1.Age of sexual maturation 2.How often organism reproduces 3.# offspring during each event Note: These traits are evolutionary outcomes, not conscious decisions by organisms Life History: traits that affect an organism’s schedule of reproduction and survival

11. Semelparity Big-bang reproduction Many offspring produced at once Individual often dies afterwards Less stable environments Agave Plant

12. Iteroparity Repeated reproduction Few, but large offspring More stable environments Lizard Critical factors: survival rate of offspring and repeated reproduction when resources are limited

13.  N/  t = B-D N = population size t = time Change in Population Size Change in population size during time interval Births during time interval Deaths during time interval = -

14. Zero population growth: B = D Exponential population growth: ideal conditions, population grows rapidly

16. Unlimited resources are rare Logistic model: incorporates carrying capacity (K) K = maximum stable population which can be sustained by environment dN/dt = r max ((K-N)/K) S-shaped curve

17. Laboratory Populations

18. Factors that limit population growth: Density-Dependent factors: population matters i.e. Predation, disease, competition, territoriality, waste accumulation, physiological factors Density-Independent factors: population not a factor i.e. Natural disasters: fire, flood, weather

19. K-selection: pop. close to carrying capacity r-selection: maximize reproductive success K-selectionr-selection Live around KExponential growth High prenatal careLittle or no care Low birth numbersHigh birth numbers Good survival of youngPoor survival of young Density-dependentDensity independent ie. Humansie. cockroaches

20. Populations fluctuate due to biotic and abiotic factors 1975-1980: peak in wolf numbers 1995: harsh winter weather (deep snow)

21. What do you notice about the population cycles of the showshoe hare and lynx?

22. Boom-and-bust cycles Predator-prey interactions Eg. lynx and snowshoe hare on 10-year cycle

23. Human Population Growth 2 configurations for a stable human population (zero population growth): A.High birth / high death B.Low birth / low death Demographic transition: occurs when population goes from A  B

24. Age-Structure Diagrams

25. Global Carrying Capacity UN predicts: 7.8 to 10.8 billion people by the year 2050 2012 = 7 billion Estimated carrying capacity = 10-15 billion? Ecological footprint: total land + water area needed for all the resources a person consumes in a pop. 1.7 hectares (ha)/person is sustainable U.S.: 10 ha/person  over K?? Limitations? Consequences? Solutions?

27. Map of ecological footprint of countries in the world (proportional sizes shown)