Geologic Dating!

1. Geologic Dating!

2. Interpreting Fossil Evidence • The natural forces that form sedimentary rock can also reveal fossils that have been hidden in layers of rock for millions of years. • As forces within the earth uplift rock and weathering forces wear away rock, fossils become exposed. • Remember: A fossil is evidence (remains or traces) of an organism that once lived. • A paleontologist is a scientist that studies fossils and the environments in which the organism lived. • Scientists try to determine its age and anatomical similarities and differences to living organisms.

3. Relative Dating • Law of Superposition – newer layers of rock/soil are on top of older layers. The lowest layer is the oldest, the top most layer, the most recent (youngest). These are called “strata”. • Stratification: enables a scientist to establish the “relative age” of something based on where it is found compared to other layers. • Relative Dating – estimating the age of a fossil by comparing its placement with that of fossils in other layers of rock to “determine the sequence in which events occurred, not how long ago they occurred.” • Problem: This dating provides no information of absolute age or age in years. • Question: Where will the oldest fossils be located? On the top or on the bottom?

4. Using Fossils to Date Rocks • The principle of Fossil succession states that fossil organisms succeed one another in a definite and determinable order. Therefore, any time period can be recognized by its fossil content. • Index Fossils – fossils of organisms that lived during a relatively short, well-defined time period. • Ammonites (mollusks) 230-208 MYA • Trilobites (similar to horseshoe crab) 400 MYA

5. Radioactive Dating • Determining the approximate age of fossils in order to determine the organisms and absolute dates they were living. This is often called Radiometric Dating. • Atomic Number – protons in nucleus (corresponding electrons) • All atoms of an element have the same atomic number, but the number of neutrons can vary. When they vary, the atom is called an “isotope”. • Radioactive Dating – calculate the age of a sample based on the amount of remaining radioactive isotope it contains. • Half-life: The length of time required for half of the radioactive atoms in a sample to decay. • For Rocks, there is Potassium-Argon or Uranium-Lead dating.

6. Specimen Dating • All living things contain Carbon-14, a radioactive isotope of Carbon-12. So for once living organisms, (versus rocks) we use Carbon Dating. • Because it is unstable, it wants to shed the extra neutrons to stabilize. • This is called “radioactive decay”, and by studying it, we can determine the how many thousands of years ago something was once living. • For instance, when an organism dies, the C-12 stays constant, but the isotope, C-14, decays. • (Carbon-14 half life is 5,730 years) • Carbon dating is really only good until about 60,000 yrs old because then there is not enough C-14 to get a good reading. • Isotopes decay at constant rates. • A half-life is the amount of time it takes for an unstable isotope to decay to one-half its original amount. • Radiometric data allows scientists to then calculate the age of a specimen.

7. Your Turn! Half-life of Carbon-14: 5,730 years Uranium-238: 4,500,000,000 years 1. You have 16 grams of an isotope with a known half life of 20 years. How much would we have in 80 years? 2. If we found in a specimen that had 75% degraded Carbon-14 (with only 25% left) then how old is this specimen? 3. Why is there controversy over the disposal of nuclear waste (U-238)? Why do we need to be concerned? (Think about the duration of its half -life!)