Answer:
V = 11π/30, 'Sketch the region' = Second Attachment, 'Sketch the solid, and a typical dish or washer' = First Attachment
Explanation:
Let's start by determining the intersection points of y = x² and x = y². The procedure would be as follows:
x = y²,
x = (x²)² = x⁴,
0 = x⁴ - x,
0 = x(x³ - 1),
x = 0, and x³ - 1 = 0
Solution(s): x = 0, and x = 1
If we want to create a 'three dimensional graph' then we would have to graph the functions y = x² and x = y² between their intersection points at x = 0, and x = 1. Then rotate the region about the line 'y = 1.' Our graph will be as demonstrated in the first attachment.
This cross section is a washer, as it is present with a hole. The top bound of the region is x = y², or y = √x. The bottom bound of the region is y = x². The large radius would be R = 1 - x², and the small radius would be r = 1 - x^1/2. The volume would then be:
![V\:=\:\pi \int _0^1\:\left[\left(1-x^2\right)^2-\left(1-x^{(1)/(2)}\right)^2\right]dx,\\=> \pi ((1)/(5)-(2)/(3)-(1)/(2)+(4)/(3))\\\\=> \pi (11)/(30)\\\\=>(11\pi )/(30)](https://img.qammunity.org/2021/formulas/mathematics/college/9o3693ldzpamzrpt2usvhqbq309ohp5ohm.png)
As you can see your volume = 11π/30. Your 'two dimensional' graph would just be a sketch of the given function's parabola(s). Take a look at the second attachment for your two dimensional graph.