Let $F$ be a field and $\langle a_1,...,a_n \rangle \subset F$.
Then given a non-zero polynomial $f \in F[X_1,...,X_n]$ is it true that if $f(a_1,...,a_n)=0$ then $(X_i - a_i)$ divides $f$ for some $i\leq n$?
Let $F$ be a field and $\langle a_1,...,a_n \rangle \subset F$.
Then given a non-zero polynomial $f \in F[X_1,...,X_n]$ is it true that if $f(a_1,...,a_n)=0$ then $(X_i - a_i)$ divides $f$ for some $i\leq n$?
Recall how the argument goes in the classical setting. Let $k$ be a field and $p(x) \in k[x]$ such that for some $a \in k$ we have $p(a)=0$. Then we can divide $p(x)$ by $(x-a)$ to leave us with an equation of the form $p(x)=q(x)(x-a)+c$ for some $c \in k$. Of course $0=p(a)=q(a)(x-a)+c=c$, so $(x-a) \mid p(x)$. The key point here is that we have a division algorithm, in particular that $k[x]$ is a Euclidean domain. Now in the case of even two variables this all begins to break down. We may think of $k[x,y]$ as $k[x][y]$ then we may still divide by $(y-a)$ by cancelling leading terms, but we are left with $p(x,y)=(y-a)q(x,y)+f(x)$. So instead of a constant term we have a polynomial in $x$, hence the last step fails.
Concretely, as mentioned in the comments, nearly any two-variable polynomial suffices. For instance $p(x,y)=1-xy$ and the point $(1,1)$.