1 / 24

Population Structure and Dynamics

Population Structure and Dynamics. Population ecology is the study of how and why populations change. A population is a group of individuals of a single species that occupy the same general area. Individuals in a population rely on the same resources

millay
Download Presentation

Population Structure and Dynamics

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Population Structureand Dynamics

  2. Population ecology is the study of how and why populations change • A population is a group of individuals of a single species that occupy the same general area. • Individuals in a population • rely on the same resources • are influenced by the same environmental factors,and • are likely to interact and breed with one another.

  3. Population ecology is the study of how and why populations change • Population ecology is concerned with • the changes in population size • factors that regulate populations over time • Populations • increase through birth and immigration to an area • decrease through death and emigration out of an area.

  4. Density and dispersion patterns are important population variables • Population density is the number of individuals of a species per unit area or volume. • Examples of population density include • the number of oak trees per square kilometer in a forest or • the number of earthworms per cubic meter in forest soil. • Ecologists use a variety of sampling techniques to estimate population densities.

  5. Density and dispersion patterns are important population variables • Within a population’s geographic range, local densities may vary greatly. • The dispersion pattern of a population refers to the way individuals are spaced within their area.

  6. Density and dispersion patterns are important population variables • Dispersion patterns can be clumped, uniform, or random. • In a clumped dispersion pattern • resources are often unequally distributed and • individuals are grouped in patches.

  7. Density and dispersion patterns are important population variables • In a uniform dispersion pattern, individuals are • most likely interacting and equally spaced in the environment.

  8. Density and dispersion patterns are important population variables • In a random dispersion pattern, individuals are spaced in an unpredictable way, without a pattern, perhaps resulting from random dispersal of windblown seeds.

  9. Life tables track survivorship in populations • Life tables track survivorship, the chance of an individual in a given population surviving to various ages. • Survivorship curves plot survivorship as the proportion of individuals from an initial population that are alive at each age. • There are three main types of survivorship curves. • Type I survivorship curves • High survival in early and middle life, followed by a rapid decline in survival later in life. • Typical of species that produce few offspring but care for them well. • Ex’s. humans, large mammals

  10. Life tables track survivorship in populations • Type II curves • Constant mortality rate/survival is experienced regardless of age; so survivorship is independent of age. • Ex. birds, some lizards, rodents • Type III curves • Low survivorship for the very young followed by high survivorship for those individuals that survive to a certain age. • Characteristic of species that produce a large number of offspring. • Ex. most marine invertebrates, fish, sea turtles

  11. 100 I 10 II Percentage of survivors (log scale) 1 III 0.1 Percentage of maximum life span

  12. Few large offspring,low mortalityuntil old age I Figure 36.UN01 Percentage of survivors II Many smalloffspring,high mortality III Percentage of maximum life span

  13. Idealized models predict patterns of population growth • Exponential growth model • The rate of population increase under ideal conditions is called exponential growth • It can be calculated using G = rN where • G is the growth rate of the population, • N is the population size, and • r is the per capita rate of increase (the average contribution of each individual to population growth). • Eventually, one or more limiting factors will restrict population growth.

  14. Idealized models predict patterns of population growth 500 450 400 350 300 250 200 150 100 50 0 Population size (N) 0 1 2 3 4 5 6 7 8 9 10 11 12 Time (months)

  15. Idealized models predict patterns of population growth • Logistic growth model • Is a description of idealized population growth that is slowed by limiting factors as population size increases. • Includes a new expression that describes the effect of limiting factors on an increasing population size. • K stands for carrying capacity, the maximum population size a particular environment can sustain.

  16. 10 8 6 4 2 0 Breeding male fur seals(thousands) 1915 1925 1935 1945 Year Data from K. W. Kenyon et al., A population study of theAlaska fur-seal herd, Federal Government Series:Special Scientific Report—Wildlife 12 (1954).

  17. G=rN Figure 36.4c (K−N) Number of individuals (N) G=rN K K 0 Time

  18. Multiple factors may limit population growth • The logistic growth model predicts that population growth will slow (increased deaths, decreased births) and eventually stop as population density increases. • Density-dependent factors = limiting factors as a result of increased density • Ex. Intraspecific competition- competition between individuals of same species for limited resources (food, nutrients, nesting sites)

  19. 6 5 4 3 2 1 0 Figure 36.5a-0 Mean number of offspring per female 0 10 20 30 40 50 60 70 80 Density of females Data from P. Arcese et al., Stability, Regulation, and the Determination of Abundancein an Insular Song Sparrow Population. Ecology 73: 805–882 (1992).

  20. Kelp perch 1.0 0.8 0.6 0.4 0.2 0 Figure 36.5b-0 Proportional mortality 0 10 20 30 40 50 60 Kelp perch density (number/plot) Data from T. W. Anderson, Predator Responses, Prey Refuges, and Density-DependentMortality of a Marine Fish, Ecology 82: 245–257 (2001).

  21. Evolution shapes life histories • The traits that affect an organism’s schedule of reproduction and death make up its life history. • Key life history traits include • age of first reproduction • frequency of reproduction • number of offspring • amount of parental care

  22. Evolution shapes life histories • Populations with r-selected life history traits • grow rapidly in unpredictable environments, where resources are abundant, • have a large number of offspring that develop and reach sexual maturity rapidly, and • offer little or no parental care.

  23. Evolution shapes life histories • Populations with K-selected traits • tend to be long-lived animals (such as bears and elephants) that develop slowly and produce few, but well-cared-for, offspring and • maintain relatively stable populations near carrying capacity. • Most species fall between these two extremes.

More Related