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Population Growth Models: Geometric and Exponential Growth Geometric Growth Exponential Growth.

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Presentation on theme: "Population Growth Models: Geometric and Exponential Growth Geometric Growth Exponential Growth."— Presentation transcript:

1 Population Growth Models: Geometric and Exponential Growth Geometric Growth Exponential Growth

2 Population Growth Models: Unrestrained Growth: How realistic?

3 Population Growth Models: Limits to Unrestrained Growth: Carrying Capacity (K) Carrying Capacity: The Maximum Population Size of a Population that a Particular Ecosystem can Sustain

4 LOGISTIC GROWTH: Rate of Population Change 10 11 12 13 Saccharomyces cervisiae (Yeast)

5 Fig. 11.9 in Molles 2008 Logistic Population Growth: Yeast K Carrying Capacity (K): Maximum Population that a Given Population can Support

6 Figs. 11.10, 11.11, 11.12, 11.26 in Molles 2008 Logistic Population Growth: Buffalo, Barnacles and Paramecia

7 Pattern of Human Population Growth? Fig. 11.26 in Molles 2013 Previous 2000 yrPrevious 40 yr

8 LOGISTIC GROWTH K: Carrying Capacity r realized : Realized Per Capita Rate of Increase r max : Intrinsic Rate of Increase: Maximum Possible Per Capita Rate of Increase (= Sigmoidal Growth Curve)

9 Figs. 11.18 in Molles 2008 (Logistic Population Growth) LOGISTIC GROWTH: Rate of Population Change dN ___ dt

10 dN ___ dT N Rate of Population Change (Logistic Growth) (dN/dT versus N) K Rate of Population Change is Maximum K2K2

11 N N r realized Exponential GrowthLogistic Growth K r max Per Capita Rate of Increase r realized K

12 LOGISTIC GROWTH: Rate of Population Change dN ____ dt r max N = ( ) 1 - N K “Brake” Term on r max Rate of Population Growth (Exponential)

13 r realized r max * ( 1 - N K ) Realized Per Capita Rate of Increase N r max r realized = (K = 100) 16 50 100 150.02 ( 1 - N K ) _______________________

14 Problem A: Suppose a population of duckweed is growing logistically (r max =.08 duckweed/duckweed/day) in a styrofoam bowl with carrying capacity = 100 plants. a)What is the rate of population change when N = 16? b) What is the rate of population change when N = 50? c) What is the rate of population change when N = 100? d) What is the rate of population change when N = 150?

15 LOGISTIC GROWTH: Predicting Population Size dN ____ dT r max N = ( ) 1 - N K

16 Problem B: Suppose sixteen duckweed (r max =.08) are growing logistically in a styrofoam bowl with carrying capacity = 100 duckweed. a) How big will the population be in ten days? a) How big will the population by in one hundred days?

17 POPULATION REGULATION: Keeping Populations in Check

18 Density Independent Factors: Exert effects INDEPENDENT of Population Density

19 Density Dependent Factors: Factors Influenced by Population Density Survivorship vs.

20 Density Dependent Factors: Factors Influenced by Population Density Fig. 9.14 in Cain et al. 2008 lxlx

21 Density Dependent Factors: Factors Influenced by Population Density Survivorship vs.

22 Fig. 9.14 in Cain et al. 2008 Density Dependent Factors: Factors Influenced by Population Density Soybean (Glycine max) lxlx

23 Fig. 16-7 in Ricklefs and Miller 20001 Population Size (N) Fecundity Density Dependent Factors: Factors Influenced by Population Density

24 Fig. 16-9 in Ricklefs and Miller 2000 Fecundity Density Dependent Factors: Factors Influenced by Population Density

25 Fig. 9.13 in Cain et al. 2008 Density Independent and Density Dependent Factors (Summary)

26 Which has more impact on Population Regulation: Density Dependent or Density Independent Factors Density Independent? Density Dependent?

27 DENSITY DEPENDENCE IS A MYTH! “The Distribution and Abundance of Animals” Andrewartha and Birch” (1954) THRIPS

28 Population Fluctuation: Density Dependent or Density Independent Factors? Fig. 16-15 in Ricklefs and Miller 2000

29 Andrewartha and Birch: Thrip Density Predicted on Basis of CLIMATIC Variables N = F (X 1, X 2, X 3, X 4 ) Effective Degree Days: Winter-Aug. 31 Rainfall: Sept. – Oct. Effective Degree Days: Sept. – Oct. Effective Degree Days: Winter-Aug. 31 (prev. year)

30 Predictions versus Observed Fig. 9-12 in Cain et al. 2008

31 Andrewartha and Birth: DENSITY-INDEPENDENT FACTORS Regulate Populations

32 Fig. 16-7 in Ricklefs et al. 2000 ECOLOGISTS COUNTER: Thrip Populations ARE Controlled by Density-Dependent Factors

33 The Debate Rages On ….

34 1 http://www.cofc.edu/~bernardoj/Genetics%20Lab/drosophila.gif 2 http://www.unexco.com/conflour.jpg 3 http://www.caudata.org/daphnia/images/Daphnia_magna_large.jpg 5 http://www.ruhr-uni-bochum.de/boga/html/Conyza.canadensis.ja05.jpg 6 http://flogaus-faust2.de/photo/amarretr.jpg 4 http://www.coffeecreekwc.org/photos/birds/Song_Sparrow.jpg 7 http://www.ces.ncsu.edu/plymouth/graphics/ent/thriplarva1.jpg 8 http://www.ruf.rice.edu/~ecology/insects/http://www.ruf.rice.edu/~ecology/insects/ Thrip%20Phloeothripidae%20short%20wgs%20blk.jpg 9 http://hortipm.tamu.edu/pestprofiles/sucking/ghthrips/thripe.jpg 10 http://greenpreferred.com/wp-content/uploads/2007/11/dsc02948.JPG 12 http://www.explorewisconsin.com/CedarCreekWinery/cedarburg_winery2b.jpg 11 http://sylviabass.com/foodie/wp-content/uploads/2007/11/potato-rosemary- bread-rising.jpghttp://sylviabass.com/foodie/wp-content/uploads/2007/11/potato-rosemary-

35 13 http://www.diwinetaste.com/html/dwt200701/images/SaccharomycesCerevisiae.jpg 14 http://student.biology.arizona.edu/honors99/group7/glycolysis.jpg 15 http://www.micro.siu.edu/micr201/images/Ethanol.gif 16 http://biology.kenyon.edu/courses/biol114/Chap08/longread_sequence.gif 17 http://www.bath.ac.uk/bio-sci/images/profiles/wheals2.gif

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