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Biology Notes Chapter 13

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The process that modern organisms have descended from ancient organisms is called evolution. ... Paleontology. Scientists who study fossils are called paleontologists. ... – PowerPoint PPT presentation

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Title: Biology Notes Chapter 13


1
Biology Notes Chapter 13
  • Evolution and Lifes Diversity

2
Evolution and Lifes Diversity
  • The process that modern organisms have descended
    from ancient organisms is called evolution.
  • Charles Darwin realized that it was the
    combination of physical traits and behaviors that
    help organisms survive and reproduce in their
    environment.
  • Darwin called these traits and behaviors fitness.

3
Charles Darwin
  • In his book The Origin of Species by Natural
    Selection, Darwin proposed that modern organisms
    have been produced through evolution.
  • Darwin hypothesized that evolution is a long,
    slow process of change in a species over time.
  • Where all new species of organisms come from
    preexisting organisms.
  • Since species have descended from common
    ancestors, Darwin called this principle common
    descent.

4
Darwin Continued
  • Darwin also argued that fitness comes through a
    process called adaptation.
  • Successful adaptations enable organisms to become
    better suited to their environment, better able
    to survive and reproduce.
  • Darwin also used the word adaptation to describe
    any inherited characteristic that increases an
    animals or plants fitness for survival.
  • For example the long neck of a giraffe make it
    more fit to survive because it allows it to eat
    the leaves off the upper portion of trees where
    there is little competition for this food source.
  • Since they are able to survive they are able to
    pass their genetic information on to future
    generations.

5
Fossils
  • Fossils are the preserved remains of ancient
    organisms.
  • There have been fossils found that greatly
    resemble the organisms of today and many found
    that are quiet different from any organism found
    today.
  • If you look on page 273 you will see the
    evolution of the camel. Provided the older layers
    have not been disturbed the camels in the lower
    levels are older than those in the layers above.

6
The Geologic Time Scale.
  • Both biologists and geologists date fossils with
    the help of a record in the rocks called the
    geologic time scale.
  • Relative dating is a technique that is used by
    scientists to determine the age of fossils
    relative to other fossils in different layers of
    roc.
  • Geologists did not know the amount of time it
    took for the different layers to form, so they
    could not determine the actual age of the
    fossils.

7
Radioactive Dating.
  • Rocks are made up of many different elements.
  • In certain rocks, some of these elements are
    radioactive.
  • Radioactive elements decay, or break down, into
    non-radioactive elements at a very steady rate.

8
Radioactive Decay Continued
  • Scientists measure the rate of radioactive decay
    in a unit called a half-life.
  • A half-life is the length of time required for
    half the radioactive atoms in a sample to decay.
  • This means that after one half-life, one half of
    the radioactive atoms in a sample have decayed.
    At the end of the second half life, one half of
    the remaining radioactive atoms have decayed.
  • In other words, one quarter of the original
    number of radioactive atoms remain after the
    second half-life reduces the remaining
    radioactive atoms by half.

9
Radioactive Dating Continued
  • Each radioactive element has a different
    half-life.
  • For example, potassium-40 has a half life of 1.3
    billion years. During that time one half of the
    potassium 40 atoms in a rock sample decay to
    argon-40.
  • Uranium-238 has a half-life of 4.5 billion years.
    During that time, on half of the uranium-238
    atoms in a rock sample decay into lead-206.
    Geologist can measure the amounts of uranium-238
    and lead-206 present in a rock sample.
  • By determining how much lead has been produced by
    decay since the rock was formed and by knowing
    the half-life of uranium, geologists can
    calculate the rock samples age.

10
Radioactive Dating Continued
  • Because radioactive dating is so accurate
    scientists call this method, absolute dating.
  • By using absolute dating scientists have divided
    the Earths history into units called eras. Eras
    are divided into periods, which in turn are
    divided into epochs. Look at pages 276 and 277
    for these different divisions.
  • Through radioactive dating scientists have
    determined that the age of the Earth is about 4.5
    billion years old.

11
The Fossil Record
  • Most fossils are found in sedimentary rock.
  • Sedimentary rocks are formed when exposure to
    rain, heat, and cold breaks down existing rocks
    into small particles of sand, silt and clay.
  • These particles are carried by streams and rivers
    into lakes or seas, and since these particles are
    heavier than water they will settle to the
    bottom.
  • Layer after layer these particles build up,
    embedding dead organisms in them.
  • As sediments pile up pressure on the lower layers
    compresses the sediments and slowly turns them
    into rock, which preserves the remains of the
    dead organisms.
  • In some cases the rock preserves the organisms
    soft parts, in other cases only the hard parts
    are preserved.
  • These remains are petrified or turned into rock.

12
Fossil Record Continued
  • The chancy process by which organisms are
    fossilized means that the fossil record is not as
    complete as we would like it to be.
  • For every organism that leaves a proper fossil,
    many die and vanish without a trace.
  • Since sedimentary rock only forms in certain
    bodies of water organisms that live in mountains
    and deserts may never become part of the fossil
    record.

13
Dating a Fossil
  • When it comes to finding out how old a fossil is
    scientist use radioactive decay to get a clue.
  • They use the radioactive form of carbon, which is
    carbon-14.
  • Carbon-14, which has a half-life of 5770 years,
    will break down to nitrogen-14.
  • So by comparing the proportions of carbon-14 and
    nitrogen-14 within a fossil, researchers can date
    the relatively young bones of early humans.
  • Carbon 14 is not useful in dating fossils more
    than about 60,000 years old because of its
    relatively short half-life.

14
Paleontology
  • Scientists who study fossils are called
    paleontologists.
  • Over the years paleontologists have collected
    millions of fossils to make up the fossil record.
  • The fossil record represents the preserved
    collective history of the Earths organisms.
  • Even though the fossil record is incomplete, it
    gives us a picture of the past of life on earth.
  • With the fossil record, paleontologists can offer
    a relatively clear picture of the evolution of
    many organisms

15
Evidence from Living Organisms
  • In the late nineteenth century, scientists
    noticed that the embryos looked so similar that
    it was difficult to tell them apart.
  • Embryos are organisms at early stages of
    development.
  • Similarities in early development indicate that
    similar genes are at work.
  • All genes in an organism are not active at the
    same time.
  • Those, which are active during the early
    development of fish, birds, humans, are related
    from a common ancestor

16
Evidence from Living Organisms Continued
  • As different organisms grow, they become less and
    less similar.
  • Genes that have changed during the course of
    evolution cause these differences in form.
  • Changes in form are produced by mutations, or
    changes in the genetic blueprint contained within
    an organisms DNA.
  • Mutations that affect the early stages of
    development are likely to be lethal.
  • Organisms with such mutations usually die as
    embryos and will never pass on there genes to the
    next generation.
  • Mutations that cause less drastic, and
    potentially useful changes in structure are
    likely to occur at later stages of growth and
    development, allowing the organisms to survive
    and reproduce.
  • This is why in the later stages of development of
    related organisms show marked differences and is
    how organisms change over time.

17
Evidence from Living Organisms Continued
  • Many of the structures of organisms are quite
    similar in early development.
  • A human, birds, horses, and whales all have cells
    that develop into limbs that look quite similar.
  • But as these organisms grow, the limbs grow into
    arms, wings, legs, and flippers that differ
    greatly in form and function.
  • These different forelimbs evolved in a series of
    evolutionary changes that altered the structure
    and appearance of the arm and leg bones of
    ancient animals.
  • Structures such as these that develop from the
    same body parts are called homologous structures.
  • Many animals have organs that look like miniature
    arms, legs, tails, or other structures.
  • These organs are vestigial organs, and seem to
    serve no useful purpose at all.

18
Similarities in Chemical Compounds
  • All organisms use DNA and or RNA to carry
    information from one generation to the next and
    to control growth and development.
  • The DNA of all eukaryotic organisms always has
    the same basic structure and replicates in the
    same way.
  • The RNAs of various species may act a little
    differently, but all RNAs are similar in
    structure from one species to the next.
  • All organisms use ATP as an energy carrier

19
What Homologies Tell Us
  • The structural and biochemical similarities among
    living organisms are best explained by Darwins
    conclusion that living organism evolved through
    gradual modification of earlier forms. (Decent
    from common ancestors.)
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