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Population and Community Ecology
Chapter 6 Population and Community Ecology
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Nature exists at several levels of complexity
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What levels of complexity make up the biosphere?
What do scientists study at each level of complexity? How do populations and communities differ?
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If INPUTS exceed OUTPUTS populations GROW
Populations are dynamic (constantly changing) The size of a population is the difference between the number of INPUTS (births and immigrations) and OUTPUTS (deaths and emigration) If INPUTS exceed OUTPUTS populations GROW If OUTPUTS exceed INPUTS populations DECREASE
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Population ecology: The study of factors that cause populations to increase or decrease.
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Factors that Regulate Population Abundance and Distribution
Population size- the total number of individuals within a defined area at a given time. (California Condor) Population density- the number of individuals per unit area at a given time. (hunting/fishing zones) Population distribution- how individuals are distributed with respect to one another. Population sex ratio- the ratio of males to females (estimate number of offspring growth in next generation) Population age structure- how many individuals fit into particular age categories. (helps predict how fast populations grow)
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Population Distribution
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Factors that Influence Population Size
Density-dependent factors- the size of the population will influence an individual’s probability of survival. Amount of available food Paramecium Food= limiting resource Carrying capacity (K)= limit to how many individuals a food supply can support
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Factors that Influence Population Size
Density-independent factors- the size of the population has no effect on the individual’s probability of survival. (tornado) Bird populations
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What factors regulate the size of a population?
What did Gause discover in his classic experiments? What is the difference between density- dependent and density-independent factors that influence population size? Give an example…
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Exponential Growth Model
Population growth models – used to predict population size at any moment in time.
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Exponential Growth Model
Growth rate- the number of offspring an individual can produce in a given time period, minus the deaths of the individual or offspring during the same period. Intrinsic growth rate- under ideal conditions, with unlimited resources, the maximum potential for growth. R
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Exponential Growth Model
Nt = N0ert R= intrinsic growth rate of a population N0 = # of reproducing individuals that are currently in the population Nt = population’s future size T= time E= the base of the natural logarithm
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Exponential Growth Model
J-shaped curve- when graphed the exponential growth model looks like this. (population is not limited by resources)
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After one year – earned $50 2nd year = 52.50 10th year = 77.57
Exponential Growth $1000 in the bank 5% annual interest rate After one year – earned $50 2nd year = 52.50 10th year = 77.57 20th = (density independent – value will grow by same % each year)
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No population can experience exponential growth indefinitely!
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“Do the math” Look at pg. 156 After reading through try to complete “YOUR TURN” on your own paper.
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Logistic Growth Model Logistic growth- when a population whose growth is initially exponential, but slows as the population approaches the carrying capacity (k). S-shaped curve- when graphed the logistic growth model produces an “S”.
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Variations of the Logistic Model
If food becomes scarce, the population will experience an overshoot by becoming larger than the spring carrying capacity and will result in a die-off, or population crash.
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Variations of the Logistic Model
Reindeer in St Paul island – Alaska Limited food, water and nest sites…
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Variations of the Logistic Model
Lynx and Hares – Canada (predator/prey)
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Variations of the Logistic Model
Wolves and Moose – Isle Royale National Park
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Reproductive Strategies
K-selected species- the population of a species that grows slowly until it reaches the carrying capacity. Ex. elephants, whales, and humans. R-selected species- the population of a species that grows quickly and is often followed by overshoots and die-offs. Ex. Mosquitoes, mice and dandelions
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Survivorship Curves
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Metapopulations Metapopulations- a group of spatially distinct populations that are connected by occasional movements of individuals between them. corridor
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What happens if you alter the r or K terms in the logistic growth model?
What did scientists learn from the records of the Hudson’s Bay Company? What is a metapopulation? How do they contribute to the preservation of biodiversity?
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Community Ecology The distribution of a species is determined by 3 factors Range of abiotic and biotic factors that it can tolerate Able to disperse Interactions with other species Competition Predation Mutualism Commensalism
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Competition Competition- the struggle of individuals to obtain a limiting resource . Gause – two species of paramecium Competitive exclusion principle – two species cannot exist if they compete for the same resources.
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Resource Patitioning
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Predation Predation- the use of one species as a resource by another species. True predators- kill their prey. Herbivores- consume plants as prey. Parasites- live on or in the organism they consume. Parasitoids- lay eggs inside other organisms.
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Mutualism Mutualism- A type of interspecific interaction where both species benefit. Acacia Trees and Pseudomyrmex ants
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Commensalism Commensalism- a type of relationship in which one species benefits but the other is neither harmed nor helped.
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Symbiotic Relationship
Relationship between two species that live in close association with each other Commensalism, mutualism, parasatism
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Keystone Species Keystone species- a species that plays a role in its community that is far more important than its relative abundance might suggest.
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Primary Succession Primary succession- occurs on surfaces that are initially devoid of soil.
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Secondary Succession Secondary succession- occurs in areas that have been disturbed but have not lost their soil.
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Aquatic Succession
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Factors that determine species richness:
Latitude Time Habitat size
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Theory of Island Biogeography
Theory of island biogeography- the theory that explains that both habitat size and distance determine species richness.
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