[tex]y=x(x-2)^2[/tex]
[tex]\implies y'=(x-2)^2+2x(x-2)=3x^2-8x+4=(3x-2)(x-2)=0[/tex]
[tex]\implies x=\dfrac23,x=2[/tex]
are the critical points, and judging by the picture alone, you must have [tex]b=\dfrac23[/tex] and [tex]a=2[/tex]. (You might want to verify with the derivative test in case that's expected.)
Then the shaded region has area
[tex]\displaystyle\int_0^2x(x-2)^2\,\mathrm dx=\dfrac43[/tex]
I'll leave the details to you.
Now, for part (iv), you're asked to find the minimum of [tex]\dfrac{\mathrm dy}{\mathrm dx}=y'[/tex], which entails first finding the second derivative:
[tex]y'=3x^2-8x+4[/tex]
[tex]\implies y''=6x-8[/tex]
setting equal to 0 and finding the critical point:
[tex]6x-8=0\implies x=\dfrac86=\dfrac43[/tex]
This is to say the minimum value of [tex]\dfrac{\mathrm dy}{\mathrm dx}[/tex] *occurs when [tex]x=\dfrac43[/tex]*, but this is not necessarily the same as saying that [tex]\dfrac43[/tex] is the actual minimum value.
The minimum value of [tex]\dfrac{\mathrm dy}{\mathrm dx}[/tex] is obtained by evaluating the derivative at this critical point:
[tex]m=\dfrac{\mathrm dy}{\mathrm dx}\bigg|_{x=4/3}=3\left(\dfrac43\right)^2-8\left(\dfrac43\right)+4=-\dfrac43[/tex]
