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Extinction

GEOG2202 – The Biosphere. Extinction. Robert Kinlocke Department of Geography and Geology UWI, Mona. Introduction . Extinction is the failure of a taxonomic group to produce descendants resulting in its disappearance world wide.

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Extinction

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  1. GEOG2202 – The Biosphere Extinction Robert Kinlocke Department of Geography and Geology UWI, Mona

  2. Introduction • Extinction is the failure of a taxonomic group to produce descendants resulting in its disappearance world wide. • Over the last 600 million years, about 4 billion species have existed but no more than 10% exist today. • Extinction is a natural, inevitable process and the loss of one species by extinction may leave an ecological niche that can be filled by others • Extinctions are measured on the basis of the number of families that made their last appearance in the fossil records. • Records of extinction are much more abundant in marine environments than they are in terrestrial environments because the fossil record is much better for marine environments

  3. Estimated number of extinctions between 1600 and 1980

  4. At the end of this session you should be able to: • Discuss the different types of extinction • Explain why some organisms are more prone to extinction than others • Describe the pattern of extinction

  5. Types of Extinction • Extirpation • Refers to a simple reduction in the range of an organism. • It means a loss of genetic diversity in the local population. • The loss can however be reversed by reintroduction. • Very often extirpation is the beginning of global extinction. • e.g: In late Pleistocene, elephants were found in Africa, Europe, Asia and the Americas but today they are restricted to Africa and India

  6. Terminal or true extinction -Is the global disappearance of a species or higher taxon such as the disappearance of mammals like the Cape lion and birds such as the Dodo.

  7. Dodo and Cape lion

  8. Quasi extinction • Refers to a situation in which species are on the verge of extinction. • e.g: tigers, Cheetahs, chimpanzees, blue and white marlin, leatherback turtles etc.

  9. Pseudo extinction or Phyletic extinction • There is no real extinction. As a result of evolutionary change, a taxon evolves into another of either equal or higher rank and this gives the impression that the ancestor has become extinct. However, the evolutionary lineage continues. e.g.: Homohabilis disappeared with the evolution of Homo sapiens. • 20% of all extinctions are pseudo extinction.

  10. Background extinction • Background extinction is a continuous , low level rate of extinction, representing the normal rate of replacement of one organism by another. • It is estimated that background rate for all species is about one per year. • Occurs due to diseases, species interaction, pseudo extinction and small scale environmental changes. • Events are abnormal, but not high rates of extinction in a region in short space of time.

  11. Mass extinction • Mass extinction is an excessively high loss of species within a brief geological time period. • The extinction rates may be twice the background rate and they affect a much broader range of organisms. • Mass extinction is either gradualistic that is occurring over a period of 100-1 million years or catastrophic occurring within a generation or up to 1000 years.

  12. Extinction susceptibility • Animals are more susceptible than plants. • Plants are more resistant because of their mechanisms of propagation: • Ability to regenerate through roots, rhizomes, seeds etc. • Ability to survive the loss of leaves and severe biomass mortality

  13. Certain characteristics make taxa extinction prone: • Large body size • Reproductive type and rate • Carnivorous nature • Taxa with specialized diets • Taxa with low dispersal abilities and those that occupy a restricted geographical ranges. • Species showing tropical distribution

  14. Body size • Large animals require greater quantities of resources and therefore exist is relatively smaller populations • Environmental change could easily affect the entire group • e.g.: some species of dinosaurs weighed over 50,000 kg. This made temperature regulation difficult.

  15. Small-bodied animals or plant parts (e.g., leaves) heat up and cool down faster; bigger and/or thicker bodies heat up and cool down more slowly • smaller/thinner bodies have a larger surface area to volume ratio. Bodies gain and lose heat out of the surface of their body; more surface area means greater gains and losses.

  16. But this association is not precisely linear • Burbidge and McKenzie (1989) observed that extinction rates were higher among species of intermediate size range 3500 -5500 g. This was termed the “critical weight range” and was based of observations of Australian terrestrial fauna

  17. Figure 1: Body-size frequency distribution of Australian terrestrial mammals, with distributions for extinct and endangered species superimposed

  18. Reproduction type and rate • Species which reproduce asexually tend to be at higher risk of extinction • Species with lower birth rates tend to be more prone to extinction. e.g.: California Condor • Correlates of birth rate may include size and trophic level. Carnivores tend to have lower birth rates • Longer gestation periods. e.g.: elephants have a gestation period of 22 months, pandas = 90 – 160 days

  19. Carnivorous Nature • As meat-eating animals become larger they are forced to prey on animals larger than themselves. Catching little animals like mice and rabbits requires more energy than it's worth. • Once they cross that line and start to prey on larger animals, the predators develop larger jaws and teeth and generally become more specialized. This makes them more vulnerable to environmental change • Additionally, because they are at higher trophic levels they require larger quantities of food

  20. Specialization Species with specialized diets or habitats are particularly vulnerable. e.g.: Giant Pandas have a diet which is comprised of 99% bamboo.

  21. Dispersal ability and geographical ranges • Dispersal rate for a species depends on either the long-distance dispersal of colonists (e.g., seeds or migrating animals), or rapid iterative colonization of nearby habitat. Most trees, for instance, can change the boundaries of their range by 1 to 45 kilometres per century. • Species with intrinsically low colonization ability may face extinction as the present habitat becomes unsuitable.  Predicted shifts of up to 100's of kilometres per century are obviously beyond the dispersal ability of most trees.   Such species would face extinction as climatic zones shift.

  22. Endemic species with narrow ranges are particularly prone to extinction • e.g. Jamaican Iguana and Black Billed Parrot (at risk of extinction)

  23. Species showing tropical distributions • Abundance tends to be lower in the tropics

  24. The End

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