Answer
$$0$$
Work Step by Step
Stoke's Theorem: Let us consider that $C$ be the closed curve which encloses surface $S$ for a vector field $F$. This also states that the line integral and the surface integral must be equal. That is,
$\oint_C F \ dx=\iint_S (\nabla \times F) \cdot n \ dS$
Here, $\nabla \times F=\begin{vmatrix} i&j&k \\ \dfrac{\partial}{\partial x} & \dfrac{\partial}{\partial y} & \dfrac{\partial}{\partial z} \\ 3 x^2 y & x^3+2yz^2 & 2y^2 z \end{vmatrix}=(4 yz -4yz, 0, 3x^2-3x^2) =(0,0,0)$
and $n=(-z_x, -z_y,1) =(0,0,0)$
Thus, the surface integral can be computed as:
$\iint_S (\nabla \times F) \cdot n \ dS=\iint_S (0,0,0) \cdot (0,0,0) \ dS\\=0$
This means that the curl is the zero vector for any closed surface by a smooth curve $C$ when the integral is zero.
