Determine the temperature after 10 min and illustrate by graphing the temperature function. Suppose that a kettle full of water is brought to a boil in a room with temperature $20^{\circ} C$ . After 15 the temperature of the water has decreased from $100^{\circ} C$ to $75^{\circ} C$.
Recall the formula for radioactive decay
$m(t) = m_0 e^{-rt}$ in which $\displaystyle r = \frac{\ln 2}{h}$
where
$m(t)$ = mass remaining at time $t$
$m_0$ = initial mass
$r$ = rate of decay
$t$ = time
Based from the given, we can see that
$
\begin{equation}
\begin{aligned}
Ts =& 20^{\circ} C
\\
\\
T(15) =& 75^{\circ} C
\\
\\
D_0 =& 100^{\circ}C - 20^\circ C = 80^\circ C
\end{aligned}
\end{equation}
$
So,
$
\begin{equation}
\begin{aligned}
75 =& 20 + 80 e^{-k(15)}
&& \text{Subtract each side by } 20
\\
\\
55 =& 80 e^{-k (15)}
&& \text{Divide each side by } 80
\\
\\
\frac{55}{80} =& e^{-15 k}
&& \text{Take $\ln$ of each side}
\\
\\
\ln \left( \frac{55}{80} \right) =& -15 k
&& \text{Recall } \ln e = 1
\\
\\
k =& - \frac{\displaystyle \ln \left( \frac{55}{80} \right) }{15}
&& \text{Divide each side by } -15
\\
\\
k =& 0.0250
&&
\end{aligned}
\end{equation}
$
Therefore, the temperature function will be
$T(t) = 20 + 80 e^{-0.0250 t}$
The temperature after another 10 min is $t = 25$ min, so
$
\begin{equation}
\begin{aligned}
T(25) =& 20 + 80 e^{-0.025 (25)}
\\
\\
T(25) =& 62.84^{\circ} C
\end{aligned}
\end{equation}
$
Hence, the graph is
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