Lemma 87.35.3. If $X$ is a countably indexed affine formal algebraic space, then we have $H^ n(X_{\acute{e}tale}, \mathcal{O}_ X) = 0$ for $n > 0$.
Proof. We may work with $X_{affine, {\acute{e}tale}}$ as this gives the same topos. We will apply Cohomology on Sites, Lemma 21.10.9 to show we have vanishing. Since $X_{affine, {\acute{e}tale}}$ has finite disjoint unions, this reduces us to the Čech complex of a covering given by a single arrow $\{ U_{red} \to V_{red}\} $ in $X_{affine, {\acute{e}tale}} = X_{red, affine, {\acute{e}tale}}$ (see Étale Cohomology, Lemma 59.22.1). Thus we have to show that
\[ 0 \to \mathcal{O}_ X(V_{red}) \to \mathcal{O}_ X(U_{red}) \to \mathcal{O}_ X(U_{red} \times _{V_{red}} U_{red}) \to \ldots \]
is exact. We will do this below in the case $V_{red} = X_{red}$. The general case is proven in exactly the same way.
Recall that $X = \text{Spf}(A)$ where $A$ is a weakly admissible topological ring having a countable fundamental system of weak ideals of definition. We have seen in Lemmas 87.34.4 and 87.34.5 that the object $U_{red}$ in $X_{affine, {\acute{e}tale}}$ corresponds to a morphism $U \to X$ of affine formal algebraic spaces which is representable by algebraic space and étale and $U = \text{Spf}(B^\wedge )$ where $B$ is an étale $A$-algebra. By our rule for the structure sheaf we see
\[ \mathcal{O}_ X(U_{red}) = B^\wedge \]
We recall that $B^\wedge = \mathop{\mathrm{lim}}\nolimits B/JB$ where the limit is over weak ideals of definition $J \subset A$. Working through the definitions we obtain
\[ \mathcal{O}_ X(U_{red} \times _{X_{red}} U_{red}) = (B \otimes _ A B)^\wedge \]
and so on. Since $U \to X$ is a covering the map $A \to B$ is faithfully flat, see Lemma 87.19.14. Hence the complex
\[ 0 \to A \to B \to B \otimes _ A B \to B \otimes _ A B \otimes _ A B \to \ldots \]
is universally exact, see Descent, Lemma 35.3.6. Our goal is to show that
\[ H^ n(0 \to A^\wedge \to B^\wedge \to (B \otimes _ A B)^\wedge \to (B \otimes _ A B \otimes _ A B)^\wedge \to \ldots ) \]
is zero for $n > 0$. To see what is going on, let's split our exact complex (before completion) into short exact sequences
\[ 0 \to A \to B \to M_1 \to 0,\quad 0 \to M_ i \to B^{\otimes _ A i + 1} \to M_{i + 1} \to 0 \]
By what we said above, these are universally exact short exact sequences. Hence $JM_ i = M_ i \cap J(B^{\otimes _ A i + 1})$ for every ideal $J$ of $A$. In particular, the topology on $M_ i$ as a submodule of $B^{\otimes _ A i + 1}$ is the same as the topology on $M_ i$ as a quotient module of $B^{\otimes _ A i}$. Therefore, since there exists a countable fundamental system of weak ideals of definition in $A$, the sequences
\[ 0 \to A^\wedge \to B^\wedge \to M_1^\wedge \to 0,\quad 0 \to M_ i^\wedge \to (B^{\otimes _ A i + 1})^\wedge \to M_{i + 1}^\wedge \to 0 \]
remain exact by Lemma 87.4.5. 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 (2)
Comment #7939 by David Benjamin Lim on
Comment #8180 by Aise Johan de Jong on