1. This WEEK: Lab: last 1/2 of manuscript due Lab VII Life Table for Human Pop Bring calculator! Will complete Homework 8 in lab Next WEEK: Homework 9 = Pop. Growth Problems Start early!

2. Chapter 17 Predation + Herbivory

3. Objectives Review growth in unlimited environment Geometric growth (seasonal reproduction) Exponential growth (continuous reprod.) Population Problems Growth in limiting environment Logistic model dN/dt = rN (K - N)/ K Density-dependent birth and death rates Assumptions of model Reality of models

4. Ch 14: Population Growth + Regulation dN/dt = rN dN/dt = rN(K-N)/K

5. Geometric growth: Individuals added at one time of year (seasonal reproduction) Exponential growth: individuals added to population continuously (overlapping generations) Both assume no age-specific birth /death rates Two models of population growth with unlimited resources :

6. Geometric growth: N N0N0  > 1 and g > 0  = 1 and g = 0  < 1 and g < 0 time Growth over 1 time unit: N t+1 = N t Growth over many time units: N t = t N 0

7. exponential growth: dN/dt = rN rate of contribution number change of each of in = individual X individuals population to population in the size growth population

8. dN / dt = r N r = difference between per capita birth (b) and per capita death (d) rates r = (b - d) = # ind./ind./yr

9. Exponential growth: Growth over many time units: N t = N 0 e rt Doubling time: t 2 = ln2/r r > 0 r < 0 r = 0

10. The two models describe the same data equally well: ln = r TIME Exponential

11. How does population size change through time? How does age structure change through time?

12. How to use a life table to project population size and age structure one time unit later.

13. Through time population size increases fluctuates, then becomes constant stable age distribution reached

14. With a stable age distribution, Each age class grows (or declines) at same rate ( ). Population growth rate ( ) stabilizes. Assumes survival and fecundity = constant.

15. *** What is a stable age distribution for a population and under what conditions is it reached? SAD = pop in which the proportions of individuals in the age classes remain constant through time Population can achieve a SAD only if its age-specific schedule of survival and fecundity rates remains constant through time. Any change in these will alter the SAD and population growth rate

16. Populations have the potential to increase rapidly… until balanced by extrinsic factors.

17. Population growth rate = Intrinsic Population Reduction in growth X size X growth rate rate at due to crowding N close to 0

18. Population growth predicted by the logistic model. K = carrying capacity

19. Assumptions of the exponential model 1. No resource limits 2. Population changes as proportion of current population size (∆ per capita) ∆ x # individuals -->∆ in population; 3. Constant rate of ∆; constant birth and death rates 4. All individuals are the same (no age or size structure) 1,2,3 are violated when resources become limited.

20. Population growth rates become lower as population size increases. Assumption of constant birth and death rates is violated. Birth and/or death rates must change as pop. size changes.

21. Population equilibrium is reached when birth rate= death rate. Those rates can change with density (= density-dependent).

22. Density-dependent factors lower survival.

23. Reproductive variables affected by habitat quality (K is lowered).

24. Reproductive variables are density- dependent.

25. r (intrinsic rate of increase) decreases as a linear function of N. Population growth is density-dependent. rmrm r r0r0 N K slope = r m /K

26. Describes a population that experiences negative density-dependence. Population size stabilizes at K, carrying capacity dN/dt = r m N(K-N)/K, dN/dt = r m N(1-N/K) where r m = maximum rate of increase w/o resource limitation = ‘intrinsic rate of increase’ K = carrying capacity (K-N)/K = environmental break (resistance) = proportion of unused resources Logistic equation

27. Logistic (sigmoid) growth occurs when the population reaches a resource limit. Inflection point at K/2 separates accelerating and decelerating phases of population growth; point of most rapid growth

28. Logistic curve incorporates influences of decreasing per capita growth rate and increasing population size. Specific

29. Assumptions of logistic model: Population growth is proportional to the remaining resources (linear response) All individuals can be represented by an average (no change in age structure) Continuous resource renewal (constant E) Instantaneous responses to crowding No time lags. K and r are specific to particular organisms in a particular environment.

30. Logistic equation assumes: Instantaneous feedback of K onto N If time lags in response --> fluctuation of N around K Longer lags---> more fluctuation; may crash. N K time

31. Models with density-dependence: Built-in time delay ---> can’t continually adjust Patterns of oscillations depend on value of r (=b-d) >>2 = chaos

32. Density-dependent factors drive populations toward equilibrium (stable population size), BUT they also fluctuate around equilibrium due to: changes in environmental conditions chance intrinsic dynamics of population responses

33. What controls population size? time N density-dependent chance density-independent K

34. How well do populations fit the logistic growth model?

35. Population dynamics reflect a complex interaction of biotic and abiotic influences, and are rarely stable. Review Ch 15: Temporal and Spatial Dynamics of Populations

36. What is K, the carrying capacity of the planet?

37. Ecological footprints of some nations already exceed available ecological capacity.

38. Objectives Review growth in unlimited environment Geometric growth (seasonal reproduction) Exponential growth (continuous reprod.) Population Problems Growth in limiting environment Logistic model dN/dt = rN (K - N)/ K Density-dependent birth and death rates Assumptions of model Reality of models

39. Vocabulary