91Ó°ÊÓ

The trying to follow has been the warmth conduction law:

$\frac{\mathrm{Δ}Q}{\mathrm{Δ}t}=k_{t}A\frac{dT}{dx}$

The warmth capacity is stated with $k_t$Examine the diagram follows, then evaluate the derivation of all this problem to relation to $x$and let $\mathrm{Δ}t→dt,\mathrm{Δ}Q→dQ$, giving us:

$\frac{d^{2}Q}{dxdt}=k_{t}A\frac{d^{2}T}{d{x}^2}$

The temperature is calculated using the the subsequent equation:

$Q=mc\mathrm{Δ}T$

The heft is determined by multiplying the length of the slice by both the packing density, as follows:

$Q=c\mathrm{ÒÏ}\mathrm{Δ}V\mathrm{Δ}T$

$\mathrm{Δ}V=A\mathrm{Δ}x$is that the volumetric, and $A$is that the larger surface section, thus:

$\frac{dQ}{dx}=c\mathrm{ÒÏ}AdT$

$\begin{array}{r}\frac{d^{2}Q}{dxdt}=c\mathrm{ÒÏ}A\frac{dT}{dt}\end{array}$

$\begin{array}{r}c\mathrm{ÒÏ}A\frac{dT}{dt}=−k_{t}A\frac{d^{2}T}{d{x}^2}\\ \end{array}$

$\frac{dT}{dt}=K\frac{d^{2}T}{d{x}^2}$

$K=\frac{k_t}{c\mathrm{ÒÏ}A}$

Perhaps we must always show that such regression relation is simply the differential equation's response.

$T(x,t)=T_0+\frac{A}{\sqrt{t}}{e}^{−x^2/4Kt}$

Calculation (3)'s LHS was even as continues to follow:

$\begin{array}{c}\mathrm{LHS}=\frac{\mathrm{∂}}{\mathrm{∂}t}\left[T_0+\frac{A}{\sqrt{t}}{e}^{−x^2/4Kt}\right]\\ \end{array}$

localid="1650352081120" $\mathrm{LHS}=−\frac{1}{2}\frac{A}{t^{3/2}}{e}^{−x^2/4Kt}+\frac{A}{t^{5/2}}\frac{x^2}{4K}{e}^{−x^2/4Kt}$

Calculation (3) has had the relevant RHS:

$\begin{array}{c}\text{RHS}=−K\frac{\mathrm{∂}}{\mathrm{∂}x}\frac{\mathrm{∂}}{\mathrm{∂}x}\left[T_0+\frac{A}{\sqrt{t}}{e}^{−x^2/4Kt}\right]\end{array}$

$\text{RHS}=−\frac{A}{\sqrt{t}}\frac{1}{2t}\frac{\mathrm{∂}}{\mathrm{∂}x}\left[x{e}^{−x^2/4Kt}\right]$

$\begin{array}{c}\mathrm{RHS}=−\frac{A}{\sqrt{t}}\frac{1}{2t}\frac{\mathrm{∂}}{\mathrm{∂}x}\left[e^{−x^2/4Kt}−\frac{x^2}{2Kt}{e}^{−x^2/4Kt}\right]\\ \end{array}$

$\mathrm{RHS}=−\frac{1}{2}\frac{A}{t^{3/2}}{e}^{−x^2/4Kt}+\frac{A}{t^{5/2}}\frac{x^2}{4K}{e}^{−x^2/4Kt}$

They still must plan that approach.

$\frac{T(x,t)−T_0}{A}=\frac{1}{\sqrt{t}}{e}^{−x^2/4Kt}$

$I$have used following syntax to print the road as an element of localid="1650354167789" $x$for varying values of $t$, the variables of localid="1650354177813" $t$will still be in terms of both the fixed localid="1650354173027" $K$, the constants are:

localid="1650354128505" $t_1=\frac{0.01}{K}{t}_2=\frac{0.1}{K}{t}_3=\frac{1.0}{K}$