In mathematics, the base change theorems relate the direct image and the inverse image of sheaves. More precisely, they are about the base change map, given by the following natural transformation of sheaves:
g*(Rrf*l{F})\toRr
| *l{F}) | |
| f' | |
| *(g' |
where
\begin{array}{rcl}X'&\stackrel{g'}\to&X\\ f'\downarrow&&\downarrowf\\ S'&\stackrelg\to&S\end{array}
is a Cartesian square of topological spaces and
l{F}
Such theorems exist in different branches of geometry: for (essentially arbitrary) topological spaces and proper maps f, in algebraic geometry for (quasi-)coherent sheaves and f proper or g flat, similarly in analytic geometry, but also for étale sheaves for f proper or g smooth.
A simple base change phenomenon arises in commutative algebra when A is a commutative ring and B and A' are two A-algebras. Let
B'=B ⊗ AA'
(M ⊗ BB')A'\cong(MA) ⊗ AA'.
Here the subscript indicates the forgetful functor, i.e.,
MA
M ⊗ BB'=M ⊗ BB ⊗ AA'\congM ⊗ AA'.
Thus, the two operations, namely forgetful functors and tensor products commute in the sense of the above isomorphism.The base change theorems discussed below are statements of a similar kind.
The base change theorems presented below all assert that (for different types of sheaves, and under various assumptions on the maps involved), that the following base change map
g*(Rrf*l{F})\toRr
| *l{F}) | |
| f' | |
| *(g' |
is an isomorphism, where
\begin{array}{rcl}X'&\stackrel{g'}\to&X\\ f'\downarrow&&\downarrowf\\ S'&\stackrelg\to&S\ \end{array}
are continuous maps between topological spaces that form a Cartesian square and
l{F}
Rif*lF
lF
f*
This map exists without any assumptions on the maps f and g. It is constructed as follows: since
g'*
g'*
\operatorname{id}\tog'*\circg'*
Rrf*\toRrf*\circg'*\circg'*.
The Grothendieck spectral sequence then gives the first map and the last map (they are edge maps) in:
Rrf*\circg'*\circg'*\toRr(f\circg')*\circg'*=Rr(g\circf')*\circg'*\tog*\circRrf'*\circg'*.
Combining this with the above yields
Rrf*\tog*\circRrf'*\circg'*.
Using the adjointness of
g*
g*
The above-mentioned introductory example is a special case of this, namely for the affine schemes
X=\operatorname{Spec}(B),S=\operatorname{Spec}(A),S'=\operatorname{Spec}(A')
X'=\operatorname{Spec}(B')
lF:=\tildeM
It is conceptually convenient to organize the above base change maps, which only involve only a single higher direct image functor, into one which encodes all
Rrf*
g*Rf*(l{F})\to
| *l{F}) | |
| Rf' | |
| *(g' |
where
Rf*
f*
If X is a Hausdorff topological space, S is a locally compact Hausdorff space and f is universally closed (i.e.,
X x ST\toT
T\toS
g*Rrf*lF\toRrf'*g'*lF
is an isomorphism. Indeed, we have: for
s\inS
(Rrf*l{F})s=\varinjlimHr(U,l{F})=
| r(X | |
| H | |
| s, |
l{F}), Xs=f-1(s)
and so for
s=g(t)
g*(Rrf*l{F})t=
| r(X | |
| H | |
| s, |
l{F})=
| r(X' | |
| H | |
| t, |
g'*l{F})=Rrf'*(g'*l{F})t.
To encode all individual higher derived functors of
f*
g*Rf*lF\toRf'*g'*lF
is a quasi-isomorphism.
The assumptions that the involved spaces be Hausdorff have been weakened by .
has extended the above theorem to non-abelian sheaf cohomology, i.e., sheaves taking values in simplicial sets (as opposed to abelian groups).
If the map f is not closed, the base change map need not be an isomorphism, as the following example shows (the maps are the standard inclusions) :
\begin{array}{rcl} \emptyset&\stackrel{g'}\to&C\setminus\{0\}\\ f'\downarrow&&\downarrowf\\ \{0\}&\stackrelg\to&C \end{array}
One the one hand
f'*g'*lF
lF
C\setminus\{0\}
\pi1(X)
g*f*lF
\pi1(X,x)
lFx
x\ne0
To obtain a base-change result, the functor
f*
Rf!
f:X\toS
Rf!lF
(Rf!lF)s=\begin{cases}lFs&s\inX,\ 0&s\notinX.\end{cases}
In general, there is a map
Rf!lF\toRf*lF
g*Rf!lF\toRf'!g'*lF.
Proper base change theorems for quasi-coherent sheaves apply in the following situation:
f:X\toS
l{F}
lFx
lOS,
p\ge0
s\mapsto\dimk(s)Hp(Xs,l{F}s):S\toZ
s\mapsto\chi(l{F}s)
\chi(l{F})
p\ge0
s\mapsto\dimk(s)Hp(Xs,l{F}s)
Rpf*l{F}
Rpf*l{F} ⊗ l{OS}k(s)\to
| p(X | |
| H | |
| s, |
l{F}s)
is an isomorphism for all
s\inS
Furthermore, if these conditions hold, then the natural map
Rp-1f*l{F} ⊗ l{OS}k(s)\toHp-1(Xs,l{F}s)
is an isomorphism for all
s\inS
| p(X | |
| H | |
| s, |
l{F}s)=0
s\inS
Rp-1f*l{F} ⊗ l{OS}k(s)\toHp-1(Xs,l{F}s)
is an isomorphism for all
s\inS
As the stalk of the sheaf
Rpf*lF
These statements are proved using the following fact, where in addition to the above assumptions
S=\operatorname{Spec}A
0\toK0\toK1\to … \toKn\to0
Hp(X x S\operatorname{Spec}-,l{F} ⊗ A-)\toHp(K\bullet ⊗ A-),p\ge0
A
The base change map
g*(Rrf*l{F})\toRr
| *l{F}) | |
| f' | |
| *(g' |
lF
X
g:S' → S
A far reaching extension of flat base change is possible when considering the base change map
Lg*Rf*(l{F})\to
| *l{F}) | |
| Rf' | |
| *(Lg' |
Lg*
lO
g*lG=lOX
| ⊗ | |
| g-1lOS |
g-1lG
g*
Lg*
S
f
lF
| b(l{O} | |
| D | |
| X-mod) |
l{O}X
lF
X
S'
S
x\inX
s'\inS'
f(x)=s=g(s')
p\ge1
| l{O | |
| \operatorname{Tor} | |
| S,s |
lF
f
D-(f-1lOS-mod)
lF'
(lF')i
f-1lOS
i
[m,n]
[m,n]
lG
D-(f-1lOS-mod)
\operatorname{Tor}i(lF,lG)=0
i
[m,n]
g
l{O}S'
g
One advantage of this formulation is that the flatness hypothesis has been weakened. However, making concrete computations of the cohomology of the left- and right-hand sides now requires the Grothendieck spectral sequence.
Derived algebraic geometry provides a means to drop the flatness assumption, provided that the pullback
X'
S'
X'=\operatorname{Spec}(B'
| L | |
| ⊗ | |
| B |
A)
Lg*Rf*l{F}\toRf'*Lg'*l{F}
Lg*=g*
In the above form, base change has been extended by to the situation where X, S, and S' are (possibly derived) stacks, provided that the map f is a perfect map (which includes the case that f is a quasi-compact, quasi-separated map of schemes, but also includes more general stacks, such as the classifying stack BG of an algebraic group in characteristic zero).
Proper base change also holds in the context of complex manifolds and complex analytic spaces.The theorem on formal functions is a variant of the proper base change, where the pullback is replaced by a completion operation.
The see-saw principle and the theorem of the cube, which are foundational facts in the theory of abelian varieties, are a consequence of proper base change.
A base-change also holds for D-modules: if X, S, X', and S' are smooth varieties (but f and g need not be flat or proper etc.), there is a quasi-isomorphism
g\dagger\intflF\to\intf'g'\daggerlF,
-\dagger
\int
lF
f:X → S
lF
Closely related to proper base change is the following fact (the two theorems are usually proved simultaneously): let X be a variety over a separably closed field and
l{F}
Xet
Hr(X,l{F})
l{F}
Under additional assumptions, extended the proper base change theorem to non-torsion étale sheaves.
In close analogy to the topological situation mentioned above, the base change map for an open immersion f,
g*f*lF\tof'*g'*lF
f!
g*f!lF\tof'!g*lF.
Rf!:=Rp*j!
f=p\circj
g*
Rf!
For the structural map
f:X\toS=\operatorname{Spec}k
Rf!(lF)
| * | |
| H | |
| c(X, |
lF)
Similar ideas are also used to construct an analogue of the functor
Rf!
X
S'
f*Rig*lG → Rig'*f'*lG
lG
S'
g*Rif*lF → Rif'*g'*lF