Maths help (1 Viewer)

Farhanthestudent005 · Sep 7, 2021

Please help. Will appreciate it . Thanks

icycledough · Sep 7, 2021

It would help to use Newton's Law of Cooling (which is T = T0 + Ce^-kt); T0 would be -10 (temperature of freezer), then to find C, you sub in t = 0 and T = 14 (initial temperature). Then use t = 25 and T = 11 to find k. Then once you have the whole formula, you should be able to do a) and b).

For a), sub in t = 300 (REMEMBER, we are using seconds, so everything must be same units; alternatively, you can use minutes, but it is more tedious)

For b), sub in T = -8 and find the value of t

CM_Tutor · Sep 8, 2021

You can also solve this starting directly from Newton's Law of Heating and Cooling, which states that the rate of change of the temperature of an object is proportional to the difference between its temperature and that of its surroundings.

So, let $D$ be the difference between the temperature of the piece of meat and the temperature of its surroundings (which we know is $-10\ ^\circ \text{C}$ . It follows that the temperature is decreasing and so

$\cfrac{dD}{dt} = -kD \qquad \qquad \text{for some constant $k > 0$}$

The solution of this differential equation is

$D=D_0e^{-kt}$

where $D_0$ is the temperature difference at $t = 0$ , and thus $D_0 = 14 - -10 = 24\ ^\circ \text{C}$ .

We are given the constraint that, at $t = 25\ \text{s}$ , $D = 11 - -10 = 21\ ^\circ \text{C}$ and so:

$\begin{align*} \text{At $t = 25$ s, $D = 21\ ^\circ$C:} \qquad 21 &= 24e^{-k \times 25} \\ \cfrac{21}{24} &= \cfrac{1}{e^{25k}} \\ \cfrac{8}{7} &= e^{25k} \\ \ln{\cfrac{8}{7}} &=25k \\ k &= \cfrac{1}{25}\ln{\cfrac{8}{7}} \end{align*}$

So, after 5 min (300 s), the temperature difference is:

$\begin{align*} \text{At $t = 300$ s:} \qquad D &= 24e^{-k \times 300} \\ &= 24e^{-\frac{300}{25}\ln\frac{8}{7}} \qquad \qquad \text{which you can shove into a calculator to get 4.834..., or you can simplify} \\ &= 24e^{\ln{\left(\frac{8}{7}\right)^{-12}}} \\ &= 24\left(\cfrac{8}{7}\right)^{-12} \\ &= 24\left(\cfrac{7}{8}\right)^{12} \\ &= \cfrac{2^3 \times 3 \times 7^{12}}{(2^3)^{12}} \\ &= \cfrac{3 \times 7^{12}}{2^{33}} \\ &= 4.834...\ ^\circ\text{C} \end{align*}$

So, the temperature after 5 minutes is:

$\begin{align*} D &= T - -10 \\ T &= D - 10 \\ &= 4.834... - 10 \\ &= -5.16598...\ ^\circ\text{C} \\ &\approx -5.17\ ^\circ\text{C} \qquad \text{(3 sig. fig.)} \end{align*}$

And, the temperature will reach $-8\ ^\circ\text{C (which is $D = -8 - -10 = +2\ ^\circ$C)}$ when:

$\begin{align*} \text{At $D = 2\ ^\circ$C:} \qquad 2 &= 24e^{-\frac{t}{25}\ln\frac{8}{7}} \\ e^{\frac{t}{25}\ln\frac{8}{7}} &= 12 \\ \cfrac{t}{25}\ln\cfrac{8}{7} &= \ln{12} \\ t &= \cfrac{25\ln{12}}{\ln{8} - \ln{7}} \\ &= 465.228...\ \text{s} \\ &\approx 7\ \text{min}\ 45.2\ \text{s} \qquad \text{(nearest 0.1 s)} \end{align*}$

Maths help (1 Viewer)

Farhanthestudent005

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icycledough

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CM_Tutor

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