$(G,F)$-points on $\mathbb{Q}$-algebraic varieties

Abstract: Let $G\in \mathbb{Q}[x,y,z]$ be a polynomial, and let $V(G)$ be the $\mathbb{Q}$-algebraic variety corresponding to $G$, i.e., $V(G)={P\in\mathbb{Q}^3~|~G(P)=0}$. Let [\begin{split} F:\quad &\mathbb{Q}^3\rightarrow \mathbb{Q}^3,\ &(x,y,z)\mapsto (f(x),f(y),f(z)) \end{split}] be a vector function, where $f\in \mathbb{Q}[x]$. It is easy to know that the function obtained by the composition of $G$ and $F$, denoted as $G\circ F$, is still in $\mathbb{Q}[x,y,z]$. Moreover, let $V(G\circ F)$ be the $\mathbb{Q}$-algebraic variety corresponding to $G\circ F$, i.e., $V(G\circ F)={P\in\mathbb{Q}^3~|~G\circ F(P)=0}$. A rational point $P$ is called a $(G,F)$-point on $V(G)$ if $P$ belongs to the intersection of $V(G)$ and $V(G\circ F)$, that is $P\in V(G)\cap V(G\circ F)$. Denote $\langle G,F\rangle$ as the set consisting of all $(G,F)$-points on $V(G)$. Obviously, $\langle G,F\rangle$ is a $\mathbb{Q}$-algebraic variety. In this paper, we consider the algebraic variety $\langle G,F\rangle$ for some specific functions $G$ and $F$. For these specific functions $G$ and $F$, we prove that $\langle G,F\rangle$ will be isomorphic to a certain elliptic curve. We also analyze some properties of these elliptic curves.