Question #c4d7e

1 Answer
Stefan V.
Dec 29, 2014

A quick way to solve nuclear half-life problems is by remembering that, esentially, you are dividing whatever amount you have by 2 for every half-life.

So, if you start with, say, 100 g of a radioactive isotope that has a half-life of 1 million years, you will have

100/2 = 50 "g" after the first 1 million years,

50/2 = 25 "g" after another 1 million years,

25/2 = 12.5 "g" after another 1 million years,

12.5/2 = 6.25 "g" after another 1 million years, and so on...

So, for this example, you are left with 1/4th of the original sample after 2 "cycles". Therefore, since, in your case, the element's half-life is 703 million, 2 "cycles" mean

703 + 703 = 1406 million = 1.4 billion years.

If the problem would have asked for, say, 1/16th of the original sample, that would have corresponded to

1/(2)^("number of cycles") = 1/16, so you'd have

2^("number of cycles") = 16 -> 4 cycles. Therefore,

4*703 "million" = 2812 "million" = 2.8 "billion years" need to pass to reach 1/16th of the original sample.

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