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Radioactive Half-Lives. perform simple, non-logarithmic half life calculations. graph data from radioactive decay and estimate half life values. graph.

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Presentation on theme: "Radioactive Half-Lives. perform simple, non-logarithmic half life calculations. graph data from radioactive decay and estimate half life values. graph."— Presentation transcript:

1 Radioactive Half-Lives

2 perform simple, non-logarithmic half life calculations. graph data from radioactive decay and estimate half life values. graph data from radioactive decay and infer an exponential relationship between measured radioactivity and elapsed time.

3 Ans:B B

4 In P30, we are concerned with the rate at which decay occurs If we construct a graph of the number of atoms vs. time of a particular radioactive isotope, we would find the following:

5 The graph is exponential, so there must be an exponential relationship between the number of nuclei decaying and time. In one period of time, one half of the initial nuclei, N o, decay. In another period of time, one half of one half (1/4N o ) decay.

6 Once a radioactive element has undergone decay it is changed into something else (trasmuted). This means that the number of parent nuclei is continuously decreasing. A quantitative measure of longevity of a particular isotope is its half-life. This is the time it takes one half of a radioactive sample to decay.

7 A mathematical equation that can model this decay is:

8 Sometimes questions are phrased with N = number of nuclei, but this is not practical in real life. More often, N = a mass of a radioactive material (kg). Other times, N is expressed as an activity, the number of decays per second: N = activity of radioactive material (Bq).

9 Some elements have very short half-lives: polonium-214 has a half-life of 1.64 x 10 -4 s, krypton-89 is 3.16 min uranium-238 is 4.47 x 10 9 years indium-115 is 4.41 x 10 14 years.

10 We can calculate the number of half lives of a substance by taking the time it is decaying for and dividing by the time of one half life.

11 Radon-222 has a half-life of 3.83 days. How many half-lives have passed after one year? If we start off with 10 mg of this sample, how much remains after a year? Answer:95 Answer:2.05x10 -34 kg

12 The t 1/2 of strontium is 28.5 years. What percentage of the original sample remains after 100 years? A sample of putnamium-11 has a half life of 20 weeks. After 52 weeks, its activity is 18.0 Bq. What was the sample’s original activity? Answer: 8.79% 109 Bq

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