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Absolute Age Using Radioactive Dating Uranium-235 (U-235) decays to become Lead (Pb) How do geologists date rocks? Radiometric dating! P1 Radioactive elements were incorporated into the Earth when the Solar System formed. All rocks and minerals contain tiny amounts of radioactive elements. Radioactive elements are unstable, they breakdown spontaneously into more stable atoms over time, a process known as radioactive decay. Radioactive decay occurs at a constant rate, specific to each radioactive isotope. This rate of decay is expressed as a half-life. A half-life is the amount of time it takes half a radioactive sample to decay into its stable product. Since the 1950s, geologists have used radioactive elements as natural "clocks" for determining numerical ages of certain types of rocks. P2 Radiometric clocks are "set" when each rock forms. "Forms" means the moment an igneous rock solidifies from magma, a sedimentary rock layer is deposited, or a rock heated by metamorphism cools off. It's this resetting process that gives us the ability to date igneous and metamorphic rocks formed at different times in earth’s history. P3 A commonly used radiometric dating technique relies on the decay of potassium (40K) to argon (40Ar). The radioactive material is referred to as the “parent” material. The stable element it decays into is the “daughter” material. Precise measurements of the ratio of 40K to 40Ar in an igneous rock can tell us the amount of time that has passed since the rock formed. If an igneous or other rock is metamorphosed, its radiometric clock is reset, and potassium-argon measurements can be used to tell the number of years that has passed since metamorphism. In both rock types, the absolute age is determined by ratio of parent material to daughter material. P4 Carbon-14 is a method used for young (less than 50,000 year old) sedimentary rocks. This method relies on the uptake of a naturally occurring radioactive isotope of carbon (carbon-14) by all living things. When living things die, they stop taking in carbon-14, and the radioactive clock is "set"! Any dead material incorporated with sedimentary deposits is a possible candidate for carbon-14 dating. P5 Radiometric dating has been used to determine the ages of the Earth, Moon, meteorites, ages of fossils, including early man, timing of glaciations, ages of mineral deposits, recurrence rates of earthquakes and volcanic eruptions, the history of reversals of Earth's magnetic field, and many of other geological events and processes. Modified from: http://geomaps.wr.usgs.gov/parks/gtime/radiom.htm QUESTIONS: 1. Describe the relationship between parent and daughter material. Support your response using evidence from the text. 2. Using evidence from the text, explain why the graph in the text above can be used with any radioactive material. 3. Paragraphs 1 and 4 use the term “incorporated.” Using evidence from the text, explain the meaning of the term. 4. Which of the two images above (graph or diagram) do you find the most helpful in understanding the scientific concept of half-lives? Explain your answer, cite evidence from the images in your response. 5. Explain how the process used to date metamorphic and igneous rock is different from the process used to date sedimentary rock. Cite text to support your answer. 6. What can you infer about the half-life of Carbon-14 versus the half-life of Uranium (U) and Potassium (K)? Support your response using evidence from the text.