**(i)** Subst$^{\mathrm{g}}$. $\begin{pmatrix}1+3\lambda\\-3+4\lambda\\2+6\lambda\end{pmatrix}$ into plane equation; i.e. $\begin{pmatrix}1+3\lambda\\-3+4\lambda\\2+6\lambda\end{pmatrix}\cdot\begin{pmatrix}2\\-6\\3\end{pmatrix} = k$ **M1**

**OR** any point on line (since "given")

$k = 2 + 6\lambda + 18 - 24\lambda + 6 + 18\lambda = 26$ **A1**

**[2]**

**(ii)** Working with vector $\begin{pmatrix}10+2m\\2-6m\\3m-43\end{pmatrix}$ **B1**

Subst$^{\mathrm{g}}$. into the plane equation: $\begin{pmatrix}10+2m\\2+6m\\3m-43\end{pmatrix}\cdot\begin{pmatrix}2\\-6\\3\end{pmatrix} = k$ **M1**

Solving a linear equation in $m$: $20 + 4m - 12 + 36m + 9m - 129 = 26$ **M1**

$m = 3 \Rightarrow Q = (16, -16, -34)$ **A1**

Sh. Dist. is $|m|\begin{vmatrix}2\\-6\\3\end{vmatrix} = 21$ or $PQ = \sqrt{6^2+18^2+9^2} = 21$ **A1**

**Alternate** methods that find only Sh. Dist. but not $Q$ can score **M1 A1** only

**[5]**

**(iii)** Finding 3 points in the plane: e.g. $A(1,-3,2)$, $B(4,1,8)$, $C(10,2,-43)$ **M1**

Then 2 vectors in (// to) plane: e.g. $\overrightarrow{AB} = \begin{pmatrix}3\\4\\6\end{pmatrix}$, $\overrightarrow{AC} = \begin{pmatrix}9\\5\\-45\end{pmatrix}$, $\overrightarrow{BC} = \begin{pmatrix}6\\1\\-51\end{pmatrix}$ **M1**

**OR B1 B1** for any two vectors in the plane

Vector product of any two of these to get normal to plane: $\begin{pmatrix}10\\-9\\1\end{pmatrix}$ **M1 A1**

(any non-zero multiple)

$d = \begin{pmatrix}10\\-9\\1\end{pmatrix}\cdot(\text{any position vector}) = \begin{pmatrix}10\\-9\\1\end{pmatrix}\cdot\begin{pmatrix}1\\-3\\2\end{pmatrix}$ e.g. $= 39$ **M1 A1**

$\Rightarrow 10x - 9y + z = 39$ **cao (or any correct equivalent form)**

**[6]**