Answer:
a) The differential equation is: [tex]\frac{dm}{dt} =r\,m[/tex]
with initial condition: [tex]m(0)=1\,\,kg[/tex]
b) m(t) =\,1\,\,kg\,\,e^{r\,t}
c) r=-0.22314
d) Same differential equation, but the solution function would have a different value for "r" resultant from dividing by 60:[tex]\frac{ln(0.8)}{60} =r\\r=-0.003719[/tex]
Step-by-step explanation:
Part a)
The differential equation is: [tex]\frac{dm}{dt} =r\,m[/tex]
with initial condition: [tex]m(0)=1\,\,kg[/tex]
Part b)
The solution for a function whose derivative is a multiple of the function itself, must be associated with exponential of base "e":
[tex]m(t) =\,A\,e^{r\,t}[/tex] with [tex]A = m(0) = 1\,\,kg[/tex]
So we can write the function as: [tex]m(t) =\,1\,\,kg\,\,e^{r\,t}[/tex]
Part c)
To find the constant "r", we use the information given on the amount of substance left after one hour (0.8 kg) by using t = 1 hour, and solving for "r" in the equation:
[tex]m(t) =\,1\,\,kg\,\,e^{r\,t}\\m(1) =\,1\,\,kg\,\,e^{r\,(1)}\\0.8\,\,kg=\,1\,\,kg\,\,e^{r\,(1)}\\0.8=e^{r\,(1)}\\ln(0.8)=r\\r=-0.22314[/tex]
where we have rounded the answer to the 5th decimal place. Notice that this constant "r" is negative, associated with a typical exponential decay.
Part d)
The differential equation if we measure the time in minutes would be the same, but its solution would have a different constant "r" given by the answer to the amount of substance left after 60 minutes have elapsed:
[tex]m(t) =\,1\,\,kg\,\,e^{r\,t}\\m(1) =\,1\,\,kg\,\,e^{r\,(60)}\\0.8\,\,kg=\,1\,\,kg\,\,e^{r\,(60)}\\0.8=e^{r\,(60)}\\\frac{ln(0.8)}{60} =r\\r=-0.003719[/tex]
