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1 Chapter 11 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
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2 Chapter 10 (Part 1)
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3 Why must species very high reproductive rates have a Type III survivorship curve ? If these species didn’t have a Type III survivor-ship curve the Earth would be covered with their bodies. Why must species low reproductive rates have a Type I survivorship curve ? If these species didn’t have a Type I survivor- ship curve they would be extinct.
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4 What is the expected relationship b/t reproductive rate and patterns of survival ? The greater the number offspring produced, the less energy / care the parent can invest in each offspring, the lower the survivorship of juveniles.
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5Age dxdxdxdx nxnxnxnx LxLxLxLx mxmxmxmx Lx mxLx mxLx mxLx mx X L x m x 01806601.000000 12404800.72710.7270.727 21202400.36420.7281.456 3601200.18220.3641.092 460600.091000 Total660 R 0 = R 0 =1.8193.275
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6 Generation Time ( T ) T = Sum (X L x m x ) / R 0 T = 3.275 / 1.819 T = 1.80 Per Capita Rate of Increase ( r ) r = Ln (R 0 ) / T r = Ln (1.819) / 1.80 r = 0.332
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7Age nxnxnxnx LxLxLxLx mxmxmxmx Lx mxLx mxLx mxLx mx X L x m x 06601.0000 14800.7272 22400.3642 31200.1821 4600.0910 Total R0 = R0 = R0 = R0 =
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8Age nxnxnxnx LxLxLxLx mxmxmxmx Lx mxLx mxLx mxLx mx 06601.000000 14800.72721.4541.454 22400.36420.7281.456 31200.18210.1820.546 4600.091000 Total R0 = R0 = R0 = R0 =2.3643.456
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9 Generation Time ( T ) T = Sum (X L x m x ) / R 0 T = 3.456 / 2.364 T = 1.46 Per Capita Rate of Increase ( r ) r = Ln (R 0 ) / T r = Ln (2.364) / 1.46 r = 0.589
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10 Effect of shifting reproduction to younger age classes? Increased R 0 1.819 vs. 2.364 (30% increase) Decreased T1.800 vs. 1.46 (19% decrease) Increased r0.332 vs. 0.589 (77% increase) Should natural selection favor early reproduction ? If r = “fitness”, this analysis suggests YES.
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11 Any disadvantages to earlier reproduction? Smaller mothers produce fewer, smaller, and(or) less vigorous young. Smaller mothers at a disadvantage in competition for resources, less able to provide for young. Survivorship of small mothers and young lower.
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12 Effect of increased prey density (food) on life history traits of predator? Lx:Lx: mx:mx: R0:R0: T: r: Increase ( ↑ vigor, better defenses) Increase ( ↑ eggs, ↓ abortion) Increase (given L x and m x increase) Decrease (rapid growth accelerates maturation) Increase ( given ↓T & ↑R 0 )
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13Age dxdxdxdx nxnxnxnx LxLxLxLx mxmxmxmx Lx mxLx mxLx mxLx mx X L x m x 08008501.000000 125500.05920011.811.8 215250.0292507.2514.5 35100.0123003.610.8 4550.0063502.18.4 Total850 R0 =R0 =R0 =R0 =24.7545.5
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14 Generation Time ( T ) T = Sum (X L x m x ) / R 0 T = 45.5 / 24.75 T = 1.84 Per Capita Rate of Increase ( r ) r = Ln (24.75) / 1.85 r = 1.74
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15 Type of Survivorship Curve ? Type III Most individuals die at a very young age. Those that get past juvenile period have lower mortality rate. Type of Life History Pattern ? r−selected: Life table indicates short life span, low juvenile survivorship, and high birth rates.
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16Age nxnxnxnx LxLxLxLx mxmxmxmx Lx mxLx mxLx mxLx mx X L x m x 08501.000000 18000.941000 27500.882000 37000.82410.8242.47 46500.76532.2959.18 56000.70632.11810.59 65000.58831.76410.58 72000.23530.7054.94 8500.05930.1771.42 R 0 = 7.8839.17
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17 Generation Time ( T ) T = Sum (X L x m x ) / R 0 T = 39.17 / 7.88 T = 4.97 Per Capita Rate of Increase ( r ) r = Ln (7.88) / 4.97 r = 0.415
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18 Type of Survivorship Curve ? Type I Most individuals survive juvenile age. Most mortality is in oldest age classes. Type of Life History Pattern ? K−selected: Life table indicates longer life span, high juvenile survivorship, and low birth rates.
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19 Geometric Growth Exponential Growth Logistic Population Growth Limits to Population Growth Density Dependent Density Independent
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20 When generations do not overlap, growth can be modeled geometrically. N t = N o λ t N t = Number of individuals at time t. N o = Initial number of individuals. λ = Geometric rate of increase. t = Number of time intervals or generations.
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21 Molles: Ecology 2 nd Ed. Currently 100 individuals Population rate, = 2 N t = N o t After 5 years, pop has 3200 100 x 2 5
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22 Continuous population growth in an unlimited environment can be modeled exponentially. dN / dt = r max N Appropriate for populations with overlapping generations. As population size (N) increases, rate of population increase (dN/dt) gets larger.
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23 For an exponentially growing population, size at any time can be calculated as: N t = N o er max t N t = Number individuals at time t. N 0 = Initial number of individuals. e = Base of natural logarithms. r max = Per capita rate of increase. t = Number of time intervals.
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25 As resources are depleted, population growth rate slows and eventually stops: logistic population growth. Sigmoid (S-shaped) population growth curve. Carrying capacity (K) is the number of individuals of a population the environment can support. Finite amount of resources can only support a finite number of individuals.
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28 dN/dt = r max N(1-N/K) r max = Maximum per capita rate of increase under ideal conditions. When N nears K, the right side of the equation nears zero. As population size increases, logistic growth rate becomes a small fraction of growth rate. Highest when N=K/2. N/K = Environmental resistance.
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29 Environment limits population growth by altering birth and death rates. Density-dependent factors Disease, Resource competition Density-independent factors Natural disasters, Weather
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30 Molles: Ecology 2 nd Ed. Boag and Grant - Geospiza fortis was numerically dominant finch (1,200) After drought of 1977, pop. fell to (180) Food plants failed to produce seed crop. 1983 - 10x normal rainfall caused population to grow (1,100) due to abundance of seeds and caterpillars.
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32 Grant and Grant documented several ways finches utilized cacti: Open flower buds in dry season to eat pollen Consume nectar and pollen from mature flowers Eat seed coating (aril) Eat seeds Eat insects from rotting cactus pads
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33 Finches tend to destroy stigmas, thus flowers cannot be fertilized. Wet season activity may reduce seeds available to finches during the dry season. Opuntia helleri main source for cactus finches. Negatively impacted by El Nino (1983). Stigma snapping delayed recovery. Interplay of biotic and abiotic factors.
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34 Molles: Ecology 2 nd Ed. Fig 11.20
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35 Molles: Ecology 2 nd Ed. On average, small organisms have higher rates of per capita increase and more variable populations than large organisms Fig 11.21
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36 Molles: Ecology 2 nd Ed. Populations of marine pelagic tunicate ( Thalia democratica ) grow at exponential rates in response to phytoplankton plumes Filter feeders
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37 Molles: Ecology 2 nd Ed. Algae bloom in spring off Australian coast Numerical response can increase pop. size dramatically due to extremely high reproductive rates Figure 11.22
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38 Molles: Ecology 2 nd Ed. Pacific Gray Whale ( Eschrichtius robustus ) divided into Western and Eastern Pacific subpopulations Summer here Winter here
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39 Molles: Ecology 2 nd Ed. Examined whales killed by whalers Estimated avg. annual mortality rate of 0.089 and calculated annual birth rate of 0.13 r = 0.13 - 0.089 = 0.041 Gray Whale pop. growing at 4.1% per yr
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40 Molles: Ecology 2 nd Ed. Reilly et.al. used annual migration counts from 1967- 1980 to obtain growth rate Thus from 1967-1980, pattern of growth in California Gray Whale pop fit exponential model: N t = N o e 0.025t Figure 11.22
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41 Molles: Ecology 2 nd Ed. What type of growth curve? Figure 11.27
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42 Molles: Ecology 2 nd Ed. Are we at carrying capacity? Will resources become limited for humans? Figure 11.27
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43 Molles: Ecology 2 nd Ed. Distribution of the Human Population
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44 Molles: Ecology 2 nd Ed. Variation in Human Population Density
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45 Molles: Ecology 2 nd Ed. Age Distributions for Human Populations: Predictors of Future Population Growth Population Size Will be Stable Population Size Will Decline Population Size Will Increase Rapidly Age Class % of Population
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46 Molles: Ecology 2 nd Ed. Historical and Projected Human Populations Figure 11.26
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47 Molles: Ecology 2 nd Ed. Can the current growth rate of the global human population be sustained ? If not, what will slow or reverse human population growth ? What Will the Future Bring ?
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48 Molles: Ecology 2 nd Ed. Trend of decreasing per capita availability of farmland and freshwater. Trend of decreasing total crop land, range land, and forest 13 of 15 major marine fisheries are in a state of near or total collapse. Humans already consume 40% of global primary productivity.
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49 Molles: Ecology 2 nd Ed. Death Rate Solution: Decrease Lx Malnutrition Disease Warfare Pollution Chemical Radiation Birth Rate Solution: Decrease m x Increase age of first reproduction (T) Education/employment for girls/women Decrease R 0 Universal availability of contraceptives Decrease infant mortality Increase standard of living
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50 Molles: Ecology 2 nd Ed. Green Revolution (Part 2) ??? Renewable and clean energy sources (solar, wind, hydro) Medical research to combat new and resistant diseases Warp Drive ???
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51 Molles: Ecology 2 nd Ed. Or maybe we should be doing something NOW ?
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52 Molles: Ecology 2 nd Ed. With abundant resources, pop’s can grow at geometric or exponential rates As resources depleted, pop growth rate slows, eventually stops: logistic population growth Environment limits population growth by changing birth and death rates On avg., small organisms have higher (r) and more variable pops. – while large organisms have lower (r) and less variable pops
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