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POPULATION ECOLOGY

POPULATION ECOLOGY. Density and Dispersion. Density - The number of individuals per unit area What are the three patterns of dispersion?. Patterns of Dispersion Within a Population’s Geographic Range. Clumped. Random. Uniform. Estimating Population Size. Mark re-capture method.

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POPULATION ECOLOGY

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  1. POPULATION ECOLOGY

  2. Density and Dispersion • Density - The number of individuals per unit area • What are the three patterns of dispersion?

  3. Patterns of Dispersion Within a Population’s Geographic Range Clumped Random Uniform

  4. Estimating Population Size • Mark re-capture method. • You capture 200 grasshoppers, mark them all and then release them back into the wild. A few days later you capture 100 grasshoppers and 50 of them were marked. How many grasshoppers do you estimate are in this population?

  5. N = # marked x # recaptured number marked & recaptured 200 x 100/50 = 400 Original Population is approx. 400

  6. You capture 50 rabbits, mark all them and release them back into the wild. The following week you capture 30 rabbits and 15 are marked. How many rabbits do you estimate in the population?

  7. 50 rabbits marked X 30 recaptured 15 marked recaptured Original Population is approx 100.

  8. Demography • Study of vital statistics that affect population size • Life Tables are age-specific summaries of the survival pattern of a population

  9. Life Table for Belding Ground Squirrels (Spermophilus beldini) at Tioga Pass, in the Sierra Nevada Mountains of California

  10. Age Structure – the relative number of individuals at each age commonly represented in pyramids. It shows present and future growth trends.

  11. Age Structure Pyramids

  12. Survivorship Curves • Plot of the numbers of a cohort that are alive at each age. • Survivorship curves are generally classified into three types:

  13. Survivorship Curves

  14. Life Histories • Traits that affect time of reproduction and death including: 1. Clutch size 2. Number of reproductive episodes per lifetime 3. Age at first reproduction

  15. Figure 52.6 • Species that exhibit semelparity, or “big-bang” reproduction • reproduce once and die

  16. Species that exhibit iteroparity, or repeated reproduction • Produce offspring repeatedly over time

  17. Birds with high probability of dying have larger clutch sizes

  18. Large clutch sizes mean one reproductive episode per life. • Small clutch sizes means more than one reproductive episode • Age at first reproduction is younger in large clutch size reproducers; they invest less energy in their own growth and development.

  19. Models of Population Growth • r = reproductive rate, r = b-d/N • b = births, d = deaths, N = population size • multiply both sides of the equation by N, we get: rN = b-d , rN = change in population during a given time interval: DN/ Dt = b - d

  20. Models of Population Growth • r max = the maximum rate of increase in growth of a species; intrinsic/maximum rate of increase • The equation for exponential population growth is: dN/ dt= rmaxN

  21. r max = 1 r max = .5

  22. Population Density is the number of • individuals per unit area. • Three factors affect a population’s size: • number of births • number of deaths • number of individuals who immigrate • and emigrate

  23. Exponential Growthoccurs when the individuals in a population reproduce at a constant rate. At first, the number of individuals in an exponentially growing population increases slowly, but over time the population becomes larger and larger. (J shaped curve)

  24. Logistic Growth occurs when a population’s growth slows or stops following a period of exponential growth. (S shaped curve)

  25. Exponential Growth Curve Carrying Capacity Logistic Growth Curve

  26. (K  N) dN  rmax N dt K • The logistic growth equation • Includes K, the carryingcapacity, the largest number of individuals of a population that an environment can support

  27. Table 52.3

  28. If N is less than K, then the population growth is positive and population increases ? What is occurring here?

  29. Are all examples of logistic growth?

  30. What sort of limiting factor is seen here?

  31. Density Dependent Selection

  32. A limiting factor causes population growth to decrease.

  33. Density Dependent Factors become limiting only when the per unit area – reaches a certain level Examples: competition, predation, parasitism, and disease.

  34. Density Independent Factors affect all populations in similar ways, regardless of the population size. Examplesinclude unusual weather, natural disasters, seasonal cycles, and certain human activities (such as damming rivers or cutting forests)

  35. What sort of limiting factor is seen here?

  36. Density Independent Selection

  37. K selection (density dependent • selection) • long maturation time • long lifespan • low death rate • few offspring/reproduction • several reproductive episodes • reproduces later in life • large sized offspring • parental care for young

  38. r selection (density independent selection) short maturation time short life-span high death rate many offspring/reproduction one reproductive event reproduces early in life small sized offspring no parental care

  39. Usually more than 1 limiting factor is at work

  40. Describe the population shifts seen below:

  41. Are we at carrying capacity?

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