Faithfully flat descent explained

Faithfully flat descent is a technique from algebraic geometry, allowing one to draw conclusions about objects on the target of a faithfully flat morphism. Such morphisms, that are flat and surjective, are common, one example coming from an open cover.

In practice, from an affine point of view, this technique allows one to prove some statement about a ring or scheme after faithfully flat base change.

"Vanilla" faithfully flat descent is generally false; instead, faithfully flat descent is valid under some finiteness conditions (e.g., quasi-compact or locally of finite presentation).

A faithfully flat descent is a special case of Beck's monadicity theorem.

Idea

A\toB

, the faithfully flat descent is, roughy, the statement that to give a module or an algebra over A is to give a module or an algebra over

B

together with the so-called descent datum (or data). That is to say one can descend the objects (or even statements) on

B

to

A

provided some additional data.

For example, given some elements

f1,...,fr

generating the unit ideal of A,

B=\prodi

-1
A[f
i

]

is faithfully flat over

A

. Geometrically,

\operatorname{Spec}(B)=

r
cup
i=1
-1
\operatorname{Spec}(A[f
i

])

is an open cover of

\operatorname{Spec}(A)

and so descending a module from

B

to

A

would mean gluing modules

Mi

on
-1
A[f
i

]

to get a module on A; the descend datum in this case amounts to the gluing data; i.e., how

Mi,Mj

are identified on overlaps
-1
\operatorname{Spec}(A[f
i

,

-1
f
j

])

.

Affine case

Let

A\toB

be a faithfully flat ring homomorphism. Given an

A

-module

M

, we get the

B

-module

N=MAB

and because

A\toB

is faithfully flat, we have the inclusion

M\hookrightarrowMAB

. Moreover, we have the isomorphism

\varphi:NB\overset{\sim}\toNB

of

B

-modules that is induced by the isomorphism

B\simeqB,xy\mapstoyx

and that satisfies the cocycle condition:

\varphi1=\varphi0\circ\varphi2

where

\varphii:NB\overset{\sim}\toNB

are given as:

\varphi0(nbc)=\rho1(b)\varphi(nc)

\varphi1(nbc)=\rho2(b)\varphi(nc)

\varphi2(nbc)=\varphi(nb)c

with
i(x)(y
\rho
0

yr)=y0yi-1xyiyr

. Note the isomorphisms

\varphii:NB\overset{\sim}\toNB

are determined only by

\varphi

and do not involve

M.

Now, the most basic form of faithfully flat descent says that the above construction can be reversed; i.e., given a

B

-module

N

and a

B

-module isomorphism

\varphi:NB\overset{\sim}\toNB

such that

\varphi1=\varphi0\circ\varphi2

, an invariant submodule:

M=\{n\inN|\varphi(n1)=n1\}\subsetN

is such that

MB=N

.

Here is the precise definition of descent datum. Given a ring homomorphism

A\toB

, we write:

di:B\toB

}for the map given by inserting

A\toB

in the i-th spot; i.e.,

d0

is given as

B\simeqAAB\toBAB=B

},

d1

as

B\simeqBAB\toB

}, etc. We also write

-

di

B

} for tensoring over

B

when

B

} is given the module structure by

di

.

Now, given a

B

-module

N

with a descent datum

\varphi

, define

M

to be the kernel of

d0-\varphi\circd1:N\toN

d0

B

.Consider the natural map

MB\toN,xa\mapstoxa

.The key point is that this map is an isomorphism if

A\toB

is faithfully flat. This is seen by considering the following:

\begin{array}{lccclcl} 0&\to&MAB&\to&NAB&\xrightarrow{d0-\varphi\circd1}&N

d0

BAB\\ &&\downarrow&&\varphi\circd1\downarrow&&\downarrow\varphi

d0,d1

B\circd2\\ 0&\to&N&\to&N

d0

B&\xrightarrow{d0-d1}&N

d0,d1

B\\ \end{array}

where the top row is exact by the flatness of B over A and the bottom row is the Amitsur complex, which is exact by a theorem of Grothendieck. The cocycle condition ensures that the above diagram is commutative. Since the second and the third vertical maps are isomorphisms, so is the first one.

The forgoing can be summarized simply as follows:

Zariski descent

The Zariski descent refers simply to the fact that a quasi-coherent sheaf can be obtained by gluing those on a (Zariski-)open cover. It is a special case of a faithfully flat descent but is frequently used to reduce the descent problem to the affine case.

In details, let

l{Q}coh(X)

denote the category of quasi-coherent sheaves on a scheme X. Then Zariski descent states that, given quasi-coherent sheaves

Fi

on open subsets

Ui\subsetX

with

X=cupUi

and isomorphisms

\varphiij:Fi

|
Ui\capUj

\overset{\sim}\toFj

|
Ui\capUj
such that (1)

\varphiii=\operatorname{id}

and (2)

\varphiik=\varphijk\circ\varphiij

on

Ui\capUj\capUk

, then exists a unique quasi-coherent sheaf

F

on X such that
F|
Ui

\simeqFi

in a compatible way (i.e.,
F|
Uj

\simeqFj

restricts to
F|
Ui\capUj

\simeqFi|

Ui\capUj

\overset{\varphiij

}\underset\to F_j|_).[1]

In a fancy language, the Zariski descent states that, with respect to the Zariski topology,

l{Q}coh

is a stack; i.e., a category

l{C}

equipped with the functor

p:l{C}\to

the category of (relative) schemes that has an effective descent theory. Here, let

l{Q}coh

denote the category consisting of pairs

(U,F)

consisting of a (Zariski)-open subset U and a quasi-coherent sheaf on it and

p

the forgetful functor

(U,F)\mapstoU

.

Descent for quasi-coherent sheaves

There is a succinct statement for the major result in this area: (the prestack of quasi-coherent sheaves over a scheme S means that, for any S-scheme X, each X-point of the prestack is a quasi-coherent sheaf on X.)

The proof uses Zariski descent and the faithfully flat descent in the affine case.

Here "quasi-compact" cannot be eliminated.

Example: a vector space

Let F be a finite Galois field extension of a field k. Then, for each vector space V over F,

VkF\simeq\prod\sigmaV,va\mapsto\sigma(a)v

where the product runs over the elements in the Galois group of

F/k

.

Specific descents

Étale descent

An étale descent is a consequence of a faithfully descent.

Galois descent

See also

References

Notes and References

  1. NB: since "quasi-coherent" is a local property, gluing quasi-coherent sheaves results in a quasi-coherent one.