http://www.ck12.org Chapter 11. Nuclear Chemistry
14 days, half of the original amount of phosphorus-32 has decayed. After another 14 days, half of the remaining
amount (or one-quarter of the original amount) has decayed, and so on.
FIGURE 11.9
This diagram models the rate of decay of
phosphorus-32 to sulfur-32.Different radioactive isotopes vary greatly in their rate of decay. As you can see from the examples inTable11.1,
the half-life of a radioisotope can be as short as a split second or as long as several billion years. You can simulate
radioactive decay of radioisotopes with different half-lives at the URL below.
http://www.colorado.edu/physics/2000/isotopes/radioactive_decay3.html
Some radioisotopes decay much more quickly than others.
TABLE11.1:Half-Life of Some Radioisotopes
Isotope Half-life
Uranium-238 4.47 billion years
Potassium-40 1.28 billion years
Carbon-14 5,730 years
Hydrogen-3 12.3 years
Radon-222 3.82 days
Polonium-214 0.00016 secondsProblem Solving
Problem: If you had a gram of carbon-14, how many years would it take for radioactive decay to reduce it to
one-quarter of a gram?
Solution:One gram would decay to one-quarter of a gram in 2 half-lives
( 1
2 ×
1
2 =1
4)
, or 2×5,730 years = 11,460
years.
You Try It!
Problem:What fraction of a given amount of hydrogen-3 would be left after 36.9 years of decay?
Radioactive Dating
Radioactive isotopes can be used to estimate the ages of fossils and rocks. The method is calledradioactive dating.
Carbon-14 dating is an example of radioactive dating. It is illustrated in the video at this URL: http://www.youtu
be.com/watch?v=udkQwW6aLik (11:00).