Situation 16.9.1. We are given a Noetherian ring $R$ and an $R$-algebra map $A \to \Lambda $ and a prime $\mathfrak q \subset \Lambda $. We assume $A$ is of finite presentation over $R$. In this situation we denote $\mathfrak h_ A = \sqrt{H_{A/R} \Lambda }$.
16.9 Local tricks
Let $R \to A \to \Lambda \supset \mathfrak q$ be as in Situation 16.9.1. We say $R \to A \to \Lambda \supset \mathfrak q$ can be resolved if there exists a factorization $A \to B \to \Lambda $ with $B$ of finite presentation and $\mathfrak h_ A \subset \mathfrak h_ B \not\subset \mathfrak q$. In this case we will call the factorization $A \to B \to \Lambda $ a resolution of $R \to A \to \Lambda \supset \mathfrak q$.
Lemma 16.9.2. Let $R \to A \to \Lambda \supset \mathfrak q$ be as in Situation 16.9.1. Let $r \geq 1$ and $\pi _1, \ldots , \pi _ r \in R$ map to elements of $\mathfrak q$. Assume
for $i = 1, \ldots , r$ we have
and
for $i = 1, \ldots , r$ the element $\pi _ i$ maps to a strictly standard element in $A$ over $R$.
Then, if
can be resolved, so can $R \to A \to \Lambda \supset \mathfrak q$.
Proof. We are going to prove this by induction on $r$.
The case $r = 1$. Here the assumption is that there exists a factorization $A/\pi _1^8 \to \bar C \to \Lambda /\pi _1^8$ which resolves the situation modulo $\pi _1^8$. Conditions (1) and (2) are the assumptions needed to apply Lemma 16.7.3. Thus we can “lift” the resolution $\bar C$ to a resolution of $R \to A \to \Lambda \supset \mathfrak q$.
The case $r > 1$. In this case we apply the induction hypothesis for $r - 1$ to the situation $R/\pi _1^8 \to A/\pi _1^8 \to \Lambda /\pi _1^8 \supset \mathfrak q/\pi _1^8\Lambda $. Note that property (2) is preserved by Lemma 16.2.7. $\square$
Lemma 16.9.3. Let $R \to A \to \Lambda \supset \mathfrak q$ be as in Situation 16.9.1. Let $\mathfrak p = R \cap \mathfrak q$. Assume that $\mathfrak q$ is minimal over $\mathfrak h_ A$ and that $R_\mathfrak p \to A_\mathfrak p \to \Lambda _\mathfrak q \supset \mathfrak q\Lambda _\mathfrak q$ can be resolved. Then there exists a factorization $A \to C \to \Lambda $ with $C$ of finite presentation such that $H_{C/R} \Lambda \not\subset \mathfrak q$.
Proof. Let $A_\mathfrak p \to C \to \Lambda _\mathfrak q$ be a resolution of $R_\mathfrak p \to A_\mathfrak p \to \Lambda _\mathfrak q \supset \mathfrak q\Lambda _\mathfrak q$. By our assumption that $\mathfrak q$ is minimal over $\mathfrak h_ A$ this means that $H_{C/R_\mathfrak p} \Lambda _\mathfrak q = \Lambda _\mathfrak q$. By Lemma 16.2.8 we may assume that $C$ is smooth over $R_\mathfrak p$. By Lemma 16.3.4 we may assume that $C$ is standard smooth over $R_\mathfrak p$. Write $A = R[x_1, \ldots , x_ n]/(g_1, \ldots , g_ t)$ and say $A \to \Lambda $ is given by $x_ i \mapsto \lambda _ i$. Write $C = R_\mathfrak p[x_1, \ldots , x_{n + m}]/(f_1, \ldots , f_ c)$ for some $c \geq n$ such that $A \to C$ maps $x_ i$ to $x_ i$ and such that $\det (\partial f_ j/\partial x_ i)_{i, j = 1, \ldots , c}$ is invertible in $C$, see Lemma 16.3.6. After clearing denominators we may assume $f_1, \ldots , f_ c$ are elements of $R[x_1, \ldots , x_{n + m}]$. Of course $\det (\partial f_ j/\partial x_ i)_{i, j = 1, \ldots , c}$ is not invertible in $R[x_1, \ldots , x_{n + m}]/(f_1, \ldots , f_ c)$ but it becomes invertible after inverting some element $s_0 \in R$, $s_0 \not\in \mathfrak p$. As $g_ j$ maps to zero under $R[x_1, \ldots , x_ n] \to A \to C$ we can find $s_ j \in R$, $s_ j \not\in \mathfrak p$ such that $s_ j g_ j$ is zero in $R[x_1, \ldots , x_{n + m}]/(f_1, \ldots , f_ c)$. Write $f_ j = F_ j(x_1, \ldots , x_{n + m}, 1)$ for some polynomial $F_ j \in R[x_1, \ldots , x_ n, X_{n + 1}, \ldots , X_{n + m + 1}]$ homogeneous in $X_{n + 1}, \ldots , X_{n + m + 1}$. Pick $\lambda _{n + i} \in \Lambda $, $i = 1, \ldots , m + 1$ with $\lambda _{n + m + 1} \not\in \mathfrak q$ such that $x_{n + i}$ maps to $\lambda _{n + i}/\lambda _{n + m + 1}$ in $\Lambda _\mathfrak q$. Then
in $\Lambda _\mathfrak q$. Thus we can find $\lambda _0 \in \Lambda $, $\lambda _0 \not\in \mathfrak q$ such that $\lambda _0 F_ j(\lambda _1, \ldots , \lambda _{n + m + 1}) = 0$ in $\Lambda $. Now we set $B$ equal to
which we map to $\Lambda $ by mapping $x_ i$ to $\lambda _ i$. Let $b$ be the image of $x_0 x_{n + m + 1} s_0 s_1 \ldots s_ t$ in $B$. Then $B_ b$ is isomorphic to
which is smooth over $R$ by construction. Since $b$ does not map to an element of $\mathfrak q$, we win. $\square$
Lemma 16.9.4. Let $R \to A \to \Lambda \supset \mathfrak q$ be as in Situation 16.9.1. Let $\mathfrak p = R \cap \mathfrak q$. Assume
$\mathfrak q$ is minimal over $\mathfrak h_ A$,
$R_\mathfrak p \to A_\mathfrak p \to \Lambda _\mathfrak q \supset \mathfrak q\Lambda _\mathfrak q$ can be resolved, and
$\dim (\Lambda _\mathfrak q) = 0$.
Then $R \to A \to \Lambda \supset \mathfrak q$ can be resolved.
Proof. By (3) the ring $\Lambda _\mathfrak q$ is Artinian local hence $\mathfrak q\Lambda _\mathfrak q$ is nilpotent. Thus $(\mathfrak h_ A)^ N \Lambda _\mathfrak q = 0$ for some $N > 0$. Thus there exists a $\lambda \in \Lambda $, $\lambda \not\in \mathfrak q$ such that $\lambda (\mathfrak h_ A)^ N = 0$ in $\Lambda $. Say $H_{A/R} = (a_1, \ldots , a_ r)$ so that $\lambda a_ i^ N = 0$ in $\Lambda $. By Lemma 16.9.3 we can find a factorization $A \to C \to \Lambda $ with $C$ of finite presentation such that $\mathfrak h_ C \not\subset \mathfrak q$. Write $C = A[x_1, \ldots , x_ n]/(f_1, \ldots , f_ m)$. Set
where $t_{ij}$ is a set of $rm$ variables. Note that there is a map $B \to C[y_ i, z]/(y_ iz)$ given by setting $t_{ij}$ equal to zero. The map $B \to \Lambda $ is the composition $B \to C[y_ i, z]/(y_ iz) \to \Lambda $ where $C[y_ i, z]/(y_ iz) \to \Lambda $ is the given map $C \to \Lambda $, maps $z$ to $\lambda $, and maps $y_ i$ to the image of $a_ i^ N$ in $\Lambda $.
We claim that $B$ is a solution for $R \to A \to \Lambda \supset \mathfrak q$. First note that $B_ z$ is isomorphic to $C[y_1, \ldots , y_ r, z, z^{-1}]$ and hence is smooth. On the other hand, $B_{y_\ell } \cong A[x_ i, y_ i, y_\ell ^{-1}, t_{ij}, i \not= \ell ]$ which is smooth over $A$. Thus we see that $z$ and $a_\ell y_\ell $ (compositions of smooth maps are smooth) are all elements of $H_{B/R}$. This proves the lemma. $\square$
Post a comment
Your email address will not be published. Required fields are marked.
In your comment you can use Markdown and LaTeX style mathematics (enclose it like $\pi$
). A preview option is available if you wish to see how it works out (just click on the eye in the toolbar).
All contributions are licensed under the GNU Free Documentation License.
Comments (0)