Figure 2 shows a sketch of part of the curve with equation $y = \ln(x)^2, \quad x > 0$ The finite region $R$, shown shaded in Figure 2, is bounded by the curve, the line with equation $x = 2$, the x-axis and the line with equation $x = 4$ - Edexcel - A-Level Maths Pure - Question 13 - 2021 - Paper 1

To find the exact area of region $R$, we integrate the function $y = \ln(x)^2$ from $x = 2$ to $x = 4$:

$A = \int_{2}^{4} \ln(x)^2 dx$

Using integration by parts, let:

• $u = \ln(x)^2 \Rightarrow du = \frac{2\ln(x)}{x} dx$
• $dv = dx \Rightarrow v = x$

Then,

$A = \left[ x \ln(x)^2 \right]_{2}^{4} - \int_{2}^{4} x \cdot \frac{2\ln(x)}{x} dx$

This simplifies to:

$A = \left[ 4 \ln(4)^2 - 2 \cdot 2 \ln(2) \right] - 2\int_{2}^{4} \ln(x) dx$

Next, compute the second integral using the result of the first application of integration by parts:

$\int \ln(x) dx = x \ln(x) - x + C$

Thus, calculating:

$-2\left[ x \ln(x) - x \right]_{2}^{4} = -2\left[ (4\ln(4) - 4) - (2\ln(2) - 2) \right]$

After resolving these, substitute back into the area, and simplify to yield the final answer in the form:

$A = 4(\ln(4)^2 - 2 \ln(2) + 2)$ \text{which can be expressed as } A = 4(\ln(2)^2 + 2\ln(2) + c)$$

Adjust to match the required form for integers $a$, $b$, and $c$.