G 12 C 8 G
Transcription
G 12 C 8 G
GEOLOGY 12 Name __________________ CHAPTER 8 GEOLOGIC TIME ABSOLUTE TIME: RADIOMETRIC DATING ACTIVITY AND WORKSHEET DEMO 1. Record the following: SAMPLE # ________ Number of Parent Atoms (P) ________ (natural color) Number of Daughter Atoms (D) ________ (pink) Ratio of Parent to Daughter (P:D) __________ = _________ (simplest form) Percentage of Parent Remaining: P x100 = _________ % 96 2. Complete the following table. SAMPLE Percent of Parent Atoms (P) Percent of Daughter Atoms (D) Ratio of P to D 1 100% 0% 1:0 Fraction of Parent Atoms ( ) 1 = 1 1 2 0 Number of Half-Lives 0 2 3 4 5 6 3. On the following grid, sketch a radioactive decay curve for macaronium. Your sketch must contain: • a title (“Radioactive Decay of Macaronium”) • vertical and horizontal axes labels (“Percent of Parent” and “Half Lives” respectively) • a smooth and clearly drawn decay curve for the plotted data, in pencil. ____________________________________________________ FOLLOW-UP QUESTIONS 1. If the half-life of macaronium is 500,000 years, how old is Sample #4? __________ 2. Add the ages for each of the half-lives to the horizontal axis of your graph. 3. Approximately what percentage of parent remains if a sample of macaronium was dated at 125,000 years old? ___________ 4. Use the data from “Percent Daughter Atoms” to sketch the curve of the stable daughter isotope. Label each curve as either Parent Isotope or Daughter Isotope. 5. Describe one problem you might encounter when radiometric dating very weathered rock. 6. Describe one problem you might encounter if the daughter product was a gas. ASSIGNMENT 1. How does an atom of a radioactive element change as it undergoes radioactive decay? 2. Examine the radioactive decay curve of Element X, shown in Figure 12.23. a. Find its half-life. b. Which element has this half-life? (see p.161) c. Find the time required for half of the sample to decay again (from 50 per cent to 25 per cent). Compare this value with the half-life you calculated in (a) above. Is there any similarity? d. A rock containing some Elements X is found to contain only 40 per cent of its original amount. How old is the rock? 3. Can radiometric dating be used to find the absolute age of any material? List some characteristics that would make some materials unsuitable for this dating method. 4. The half-life of carbon-14 is 5,700 years. If you start with 1.0 g of carbon 14, how much will remain after 5,700 years? 5. How much carbon-14 remains after 11,400 years (two half-lives)? 6. Estimate the ages of the following: a. A bone fragment with 50% of its original carbon 14 remaining. b. A fossilized shark's tooth with ~12% of the original carbon 14 remaining. c. A tiny piece of paper taken from the Dead Sea Scrolls with 75% of the original carbon 14 remaining. 7. What percentage of the original carbon 14 would remain in a sample of wood from a shipwreck if it was: a. 10,400years old? b. 30,000 years old? 8. Carbon 14 is incorporated into living plants from the atmosphere. From there it enters into animals. To use carbon-14 dating, the samples must have come from organisms that were once alive. With this in mind, explain: a. Why is it often difficult to find samples for carbon 14 dating on ancient shipwrecks? b. What might you expect to find on an ancient shipwreck that could be dated using carbon 14? 9. Suggest a reason why carbon dating is not suitable for finding the age of ancient fossils that are millions of years old. 10. Using the table on page 161, which radioactive isotopes would not be suitable for radiometric dating when a. testing materials that were once living? b. testing inorganic materials (matter that has never been alive)? c. dating rocks older than 1 billion years, such as meteorites? d. dating materials younger than 1000 years old? e. dating rock samples that had been heated at some time in the past? (HINT: This would drive off any gases trapped in the rock.) BONUS Plot a decay curve for the radioactive isotope thorium 232, assuming its half-life is 14 billion years.