Attached is a plot of the base with one of the cross sections (at [tex]x=0.6[/tex]).
The area of any one cross section is given by [tex]\dfrac{\pi r^2}2[/tex], where [tex]r[/tex] is the radius of the circular cross section. In terms of the sections' diameters [tex]d=2r[/tex], the area would be [tex]\dfrac{\pi\left(\frac d2\right)^2}2=\dfrac{\pi d^2}8[/tex].
Each section's diameter is determined by the vertical distance (in the x-y plane) between the curve [tex]y=3-x^5[/tex] and the x-axis ([tex]y=0[/tex]), or simply [tex]d=3-x^5[/tex]. So the area of any one cross-section for a given [tex]x[/tex] is [tex]\dfrac{\pi(3-x^5)^2}8[/tex].
The region extends from [tex]x=0[/tex] to [tex]x=3^{1/5}[/tex] (the positive root of [tex]3-x^5[/tex]), so the volume of the solid would be
[tex]\displaystyle\int_0^{3^{1/5}}\frac{\pi(3-x^5)^2}8\,\mathrm dx=\frac\pi8\int_0^{3^{1/5}}(3-x^5)^2\,\mathrm dx[/tex]
You can compute this by expanding the integrand, then integrating term by term. You should find a volume of [tex]\dfrac{75\times3^{1/5}\pi}{88}\approx3.335[/tex].
