# Motivation for the étale topology over other possibilities

In the search for a Weil cohomology theory $H$ over a field $K$ (with $\text{char}(K)=0$) for varieties in characteristic $p$, a classical argument by Serre shows that the coefficient field cannot be a subfield of $\mathbb{R}$ or of $\mathbb{Q}_p$; an obvious choice is to take $\mathbb{Q}_\ell$ for a prime $\ell \neq p$.

Now, we can try to make a Weil cohomology theory by taking the sheaf cohomology with constant sheaves with the Zariski topology, but this does not work as all cohomology vanishes.
Grothendieck's insight was that we can find a different topology, for example the étale topology. Then we can build a Weil cohomology theory with coefficients in $\mathbb{Q}_\ell$ by taking cohomology with coefficients in the constant sheaves $\mathbb{Z}/ \ell^n\mathbb{Z}$ and then taking the inverse limit with respect to $n$ and tensor with $\mathbb{Q}_\ell$: this gives $\ell$-adic cohomology.

But it is not so clear to me why the étale topology is best suited at this task. What happens if we repeat the above procedure on other sites? Does the cohomology theory we get fail to be a Weil cohomology theory?

P.S.: Information for fields other than $\mathbb{Q}_\ell$ would also be nice!

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Also, does anyone know of a reference for Serre's argument? –  Sam Derbyshire Feb 21 '10 at 18:19
The point is that for a supersingular curve E over a finite field, $End(E)\otimes Q$ is a quaternion algebra (skew field of degree 4 over Q). It can't act on a two-dimensional space over a field F unless F splits the algebra (i.e., tensoring with F gives a matrix algebra). Since $End(E)\otimes Q$ isn't split by R or Q_p, there can't be a Weil cohomology with coefficients in those fields. This is always credited to Serre because he put it in print, but was surely common knowledge, e.g., Weil surely knew it. –  JS Milne Feb 21 '10 at 18:29
I'm a bit confused by the statement that "there can't be a Weil cohomology with coefficients in those fields." Perhaps I am mis-remembering what the axiomatic definition of a Weil cohomology is, but isn't rigid cohomology supposed to be a Weil cohomology? –  B. Cais Feb 21 '10 at 19:05
@B. Cais, Sam D: The argument of Serre shows that a you can't have a Weil cohomology over say $\mathbf{F}_{p^2}$ which takes values in $\mathbf{Z}_p$. The argument breaks down for a supersingular curve over $\mathbf{F}_p$ because not all of its endomorphism ring is defined over $\mathbf{F}_p$. So for instance crystalline (resp. rigid) cohomology takes values in W(F) (resp. W(f)[1/p]) –  David Zureick-Brown Feb 21 '10 at 19:34
Actually, I have a question. Nowhere in the axioms of a Weil cohomology theory are any sort of comparison theorems specified. Why is it necessarily the case that H^1 of an elliptic curve should be of dimension 2? Of course, I think it is entirely reasonable to ask for comparison theorems, but it seems the usual definition does not have them, which leaves me wondering. In the framework of motives, it becomes even clearer that H^1 should be of dimension 2 (viewing Jacobians of curves as tightly related to their motives), so maybe that is the correct context, instead of Weil cohomology theories? –  Sam Derbyshire Apr 25 '10 at 5:01
As I understand it, we want the inverse function theorem to hold so that the étale cohomology compares favourably to singular cohomology in the complex analytic case; in particular they are isomorphic for finite coefficient abelian groups, which is what we need to set up $\ell$-adic cohomology. Will this necessarily fail if we have a topology in which the inverse function theorem fails? –  Sam Derbyshire Feb 21 '10 at 18:57
The group $H^1(X,A)$ with A a finite commutative group, should classify the A-torsors over X. In order for it to do this, the topology must split the torsors. This means you must allow etale covers, and the miracle is once you do that you get the "correct" cohomology groups in all degrees. –  JS Milne Feb 21 '10 at 19:26