$\begin{aligned}
& \mathrm{A}(\mathrm{x}, \mathrm{y}, \mathrm{z}) \text { Let } \mathrm{P}(0,3,2), \mathrm{Q}(2,0,3), \mathrm{R}(0,0,1) \
& \mathrm{AP}=\mathrm{AQ}=\mathrm{AR} \
& \mathrm{x}^2+(\mathrm{y}-3)^2+(\mathrm{z}-2)^2=(\mathrm{x}-2)^2+\mathrm{y}^2+(\mathrm{z}-3)^2=\mathrm{x}^2+ \
& \mathrm{y}^2+(\mathrm{z}-1)^2
\end{aligned}Inx yplanez=0So,x^2-4 x+4+y^2+9=x^2+y^2+1\begin{aligned}
& x=3 \
& 9+y^2-6 y+9+4=x^2+y^2+1
\end{aligned}So,\mathrm{A}(3,2,0)also\mathrm{B}(1,4,-1) & \mathrm{C}(2,0,-2)NowA B=\sqrt{4+4+1}=3\begin{aligned}
& \mathrm{AC}=\sqrt{1+4+4}=3 \
& \mathrm{BC}=\sqrt{1+16+1}=\sqrt{18}
\end{aligned}\mathrm{AB}=\mathrm{AC}isosceles\Delta & \mathrm{AB}^2+\mathrm{AC}^2=\mathrm{BC}^2rightangle\DeltaAreaof\triangle \mathrm{ABC}=\frac{1}{2} \timesbase.height\frac{1}{2} \times 3 \times 3=\frac{9}{2}SoonlyS_1$ is true