We can start off here by acknowledging that we know,

\[Q\left( 0 \right) = 250\hspace{0.5in}{\rm{and}}\hspace{0.5in}Q\left( 5 \right) = 1600\]

If we use the first condition in the equation we get,

\[250 = Q\left( 0 \right) = {Q_0}{{\bf{e}}^{k\left( 0 \right)}} = {Q_0}\hspace{0.5in} \to \hspace{0.5in}{Q_0} = 250\]

We now know the first unknown in the equation. Plugging this as well as the second condition into the equation gives us,

\[1600 = Q\left( 5 \right) = 250{{\bf{e}}^{5k}}\]

We can use techniques from earlier problems in this section to determine the value of \(k\).

\[\begin{align*}1600 & = 250{{\bf{e}}^{5k}}\\ \frac{{1600}}{{250}} & = {{\bf{e}}^{5k}}\\ \ln \left( {\frac{{32}}{5}} \right) & = 5k\\ k & = \frac{1}{5}\ln \left( {\frac{{32}}{5}} \right) = 0.3712596\end{align*}\]

Depending upon your preferences we can use either the exact value or the decimal value. Note however that because \(k\) is in the exponent of an exponential function we’ll need to use quite a few decimal places to avoid potentially large differences in the value that we’d get if we rounded off too much.

Putting all of this together the exponential growth equation for this population is,

\[\require{bbox} \bbox[2pt,border:1px solid black]{{Q = 250{{\bf{e}}^{\frac{1}{5}\ln \left( {\frac{{32}}{5}} \right)t}}}}\]

What we’re really being asked to do here is to solve the equation,

\[2000 = Q\left( t \right) = 250{{\bf{e}}^{\frac{1}{5}\ln \left( {\frac{{32}}{5}} \right)t}}\]

and we know from earlier problems in this section how to do that. Here is the solution work for this part.

\[\begin{align*}\frac{{2000}}{{250}} & = {{\bf{e}}^{\frac{1}{5}\ln \left( {\frac{{32}}{5}} \right)t}}\\ \ln \left( 8 \right) & = \frac{1}{5}\ln \left( {\frac{{32}}{5}} \right)t\\ t & = \require{bbox} \bbox[2pt,border:1px solid black]{{\frac{{5\ln \left( 8 \right)}}{{\ln \left( {{\textstyle{{32} \over 5}}} \right)}} = 5.6010}}\end{align*}\]

It will take 5.601 days for the population to reach 2000.