The answer is (3) 3 × 12.4 hours
To calculate this, we will use two equations:
[tex](1/2) ^{n} =x[/tex]
[tex]t_{1/2} = \frac{t}{n} [/tex]
where:
n - number of half-lives
x - remained amount of the sample, in decimals
[tex]t_{1/2} [/tex] - half-life length
t - total time elapsed.
First, we have to calculate x and n. x is remained amount of the sample, so if at the beginning were 16 grams of potassium-42, and now it remained 2 grams, then x is:
2 grams : x % = 16 grams : 100 %
x = 2 grams × 100 percent ÷ 16 grams
x = 12.5% = 0.125
Thus:
[tex](1/2) ^{n} =x[/tex]
[tex](0.5) ^{n} =0.125[/tex]
[tex]n*log(0.5)=log(0.125)[/tex]
[tex]n= \frac{log(0.5)}{log(0.125)} [/tex]
[tex]n=3[/tex]
It is known that the half-life of potassium-42 is 12.36 ≈ 12.4 hours.
Thus:
[tex]t_{1/2} = 12.4 [/tex]
[tex]t_{1/2} *n = t [/tex]
[tex]t= 12.4*3 [/tex]
Therefore, it must elapse 3 × 12.4 hours before 16 grams of potassium-42 decays, leaving 2 grams of the original isotope
