We consider the ring $A = \mathbf { Z } [ X , Y ]$. Let $U$ be the set of elements of $A$ of the form $X Y ^ { k }$ with $k \in \mathbf { N }$, we set $B = \mathcal { A } ( U )$. Let $S$ be a finite subset of $B$. a) Show that there exists $m \in \mathbf { N } ^ { * }$ such that $\mathcal { A } ( S ) \subset \mathcal { A } \left( \left\{ X , X Y , \ldots , X Y ^ { m } \right\} \right)$. b) Show that there exists an integer $N > 0$ such that every element of $\mathcal { A } ( S )$ is a sum of monomials of the form $\alpha X ^ { i } Y ^ { j }$ with $\alpha \in \mathbf { Z }$ and $j \leq i N$. c) Deduce that the ring $B$ does not have property (TF).
We consider the ring $A = \mathbf { Z } [ X , Y ]$. Let $U$ be the set of elements of $A$ of the form $X Y ^ { k }$ with $k \in \mathbf { N }$, we set $B = \mathcal { A } ( U )$. Let $S$ be a finite subset of $B$.\\
a) Show that there exists $m \in \mathbf { N } ^ { * }$ such that $\mathcal { A } ( S ) \subset \mathcal { A } \left( \left\{ X , X Y , \ldots , X Y ^ { m } \right\} \right)$.\\
b) Show that there exists an integer $N > 0$ such that every element of $\mathcal { A } ( S )$ is a sum of monomials of the form $\alpha X ^ { i } Y ^ { j }$ with $\alpha \in \mathbf { Z }$ and $j \leq i N$.\\
c) Deduce that the ring $B$ does not have property (TF).