To model this situation we are going to use the exponential decay function: [tex]f(t)=a(1-b)^t[/tex]
where
[tex]f(t)[/tex] is the final amount remaining after [tex]t[/tex] years of decay
[tex]a[/tex] is the initial amount
[tex]b[/tex] is the decay rate in decimal form
[tex]t[/tex] is the time in years
For substance A:
Since we have 300 grams of the substance, [tex]a=300[/tex]. To convert the decay rate to decimal form, we are going to divide the rate by 100%:
[tex]r= \frac{0.15}{100} =0.0015[/tex]. Replacing the values in our function:
[tex]f(t)=a(1-b)^t[/tex]
[tex]f(t)=300(1-0.0015)^t[/tex]
[tex]f(t)=300(0.9985)^t[/tex] equation (1)
For substance B:
Since we have 500 grams of the substance, [tex]a=500[/tex]. To convert the decay rate to decimal form, we are going to divide the rate by 100%:
[tex]r= \frac{0.37}{100} =0.0037[/tex]. Replacing the values in our function:
[tex]f(t)=a(1-b)^t[/tex]
[tex]f(t)=500(1-0.0037)^t[/tex]
[tex]f(t)=500(0.9963)^t[/tex] equation (2)
Since they are trying to determine how many years it will be before the substances have an equal mass[tex]M[/tex], we can replace [tex]f(t)[/tex] with [tex]M[/tex] in both equations:
[tex]M=300(0.9985)^t[/tex] equation (1)
[tex]M=500(0.9963)^t[/tex] equation (2)
We can conclude that the system of equations that can be used to determine how long it will be before the substances have an equal mass, [tex]M[/tex], is:
[tex] \left \{ {{M=300(0.9985)^t} \atop {M=500(0.9963)^t}} \right. [/tex]
Solving the system, we can show that it will take approximately 231.59 years for that to happen.
