Answer:
87.97028 hours
Step-by-step explanation:
Let y(t) be the density of picocuries at time t.
As the ventilation system installed brings in 500 cubic feet of air per hour that contains 4 picocuries per cubic foot, every hour there are 500*4 = 2000 picocuries  entering the room.
At the same time, 500y(t) picocuries are leaving the room.
So, the rate of change of the density of the picocuries is Â
(amount of picocuries at time t)/19000 =(amount of picocuries entering - amount of picocuries leaving at time t)/19000
That is to say,
[tex]y'(t)=\frac{20000-500y(t)}{19000}=\frac{200-5y(t)}{190}[/tex]
Let's write the equation in the standard mode by operating on this expression:
[tex]y'(t)+\frac{1}{38}y(t)=\frac{20}{19}[/tex]
This an ordinary linear differential equation of 1st order, whose integrating factor is Â
[tex]e^{t/38}[/tex]
So, the solution is
[tex]y(t)=ce^{-t/38}+40[/tex]
To find c, we use the initial value y(0)=850 and we get
c = 810
and the equation that gives the density of picocuries per cubic foot is
[tex]\boxed{y(t)=810e^{-t/38}+40}[/tex]
Now, we must look for a value of t for which y(t)=120.
[tex]y(t)=120 \Rightarrow 810e^{-t/38}+40=120\Rightarrow e^{-t/38}=\frac{8}{81}[/tex]
Taking logarithm on both sides
[tex]\frac{-t}{38}=\ln(8/81)\Rightarrow \boxed{t=87.97028\;hours}[/tex]
