Flat morphism explained

In mathematics, in particular in the theory of schemes in algebraic geometry, a flat morphism f from a scheme X to a scheme Y is a morphism such that the induced map on every stalk is a flat map of rings, i.e.,

fP\colonl{O}Y,\tol{O}X,

is a flat map for all P in X.[1] A map of rings

A\toB

is called flat if it is a homomorphism that makes B a flat A-module. A morphism of schemes is called faithfully flat if it is both surjective and flat.[2]

Two basic intuitions regarding flat morphisms are:

The first of these comes from commutative algebra: subject to some finiteness conditions on f, it can be shown that there is a non-empty open subscheme

Y'

of Y, such that f restricted to Y′ is a flat morphism (generic flatness). Here 'restriction' is interpreted by means of the fiber product of schemes, applied to f and the inclusion map of

Y'

into Y.

For the second, the idea is that morphisms in algebraic geometry can exhibit discontinuities of a kind that are detected by flatness. For instance, the operation of blowing down in the birational geometry of an algebraic surface, can give a single fiber that is of dimension 1 when all the others have dimension 0. It turns out (retrospectively) that flatness in morphisms is directly related to controlling this sort of semicontinuity, or one-sided jumping.

Flat morphisms are used to define (more than one version of) the flat topos, and flat cohomology of sheaves from it. This is a deep-lying theory, and has not been found easy to handle. The concept of étale morphism (and so étale cohomology) depends on the flat morphism concept: an étale morphism being flat, of finite type, and unramified.

Examples/non-examples

Consider the affine scheme

\operatorname{Spec}\left(\Complex[x,y,t]
x2+y2-t

\right)\to\operatorname{Spec}(\Complex[t])

induced from the obvious morphism of algebras

\begin{cases}\Complex[t]\to

\Complex[x,y,t]
x2+y2-t

\t\mapstot\\end{cases}

Since proving flatness for this morphism amounts to computing[3]

\Complex[t]
\operatorname{Tor}\left(
1
\Complex[x,y,t]
x2+y2-t

,\Complex\right),

we resolve the complex numbers

\begin{array}{lcccc} 0&\to&\Complex[t]&\xrightarrow{t}&\Complex[t]&\to&0\\ \downarrow&&\downarrow&&\downarrow&&\downarrow\\ 0&\to&0&\to&\Complex&\to&0\\ \end{array}

and tensor by the module representing our scheme giving the sequence of

\Complex[t]

-modules

0\to

\Complex[x,y,t]
x2+y2-t

\xrightarrow{t}

\Complex[x,y,t]
x2+y2-t

\to0

Because is not a zero divisor we have a trivial kernel, hence the homology group vanishes.

Miracle flatness

Other examples of flat morphisms can be found using "miracle flatness"[4] which states that if you have a morphism

f\colonX\toY

between a Cohen–Macaulay scheme to a regular scheme with equidimensional fibers, then it is flat. Easy examples of this are elliptic fibrations, smooth morphisms, and morphisms to stratified varieties which satisfy miracle flatness on each of the strata.

Hilbert schemes

The universal examples of flat morphisms of schemes are given by Hilbert schemes. This is because Hilbert schemes parameterize universal classes of flat morphisms, and every flat morphism is the pullback from some Hilbert scheme. I.e., if

f\colonX\toS

is flat, there exists a commutative diagram

\begin{matrix} X&\to&\operatorname{Hilb}S\\ \downarrow&&\downarrow\\ S&\to&S \end{matrix}

for the Hilbert scheme of all flat morphisms to

S

. Since

f

is flat, the fibers

fs\colonXs\tos

all have the same Hilbert polynomial

\Phi

, hence we could have similarly written
\Phi
Hilb
S
for the Hilbert scheme above.

Non-examples

Blowup

One class of non-examples are given by blowup maps

\operatorname{Bl}IX\toX.

One easy example is the blowup of a point in

\Complex[x,y]

. If we take the origin, this is given by the morphism

\Complex[x,y]\to

\Complex[x,y,s,t]
xt-ys
sending

x\mapstox,y\mapstoy,

where the fiber over a point

(a,b)(0,0)

is a copy of

\Complex

, i.e.,
\Complex[x,y,s,t]
xt-ys

\Complex[x,y]

\Complex[x,y]
(x-a,y-b)

\cong\Complex,

which follows from

MR

R
I

\cong

M
IM

.

But for

a=b=0

, we get the isomorphism
\Complex[x,y,s,t]
xt-ys

\Complex[x,y]

\Complex[x,y]
(x,y)

\cong\Complex[s,t].

The reason this fails to be flat is because of the Miracle flatness lemma, which can be checked locally.

Infinite resolution

A simple non-example of a flat morphism is

k[\varepsilon]=k[x]/(x2)\tok.

This is because

k

L
k[\varepsilon]

k

is an infinite complex, which we can find by taking a flat resolution of,

~\xrightarrow{\overset{}\varepsilon}~k[\varepsilon]~\xrightarrow{\varepsilon}~k[\varepsilon]\xrightarrow{\varepsilon}k[\varepsilon]\tok

and tensor the resolution with, we find that

L
k
k[\varepsilon]

k\simeq

infty
oplus
i=0

k[+i]

showing that the morphism cannot be flat. Another non-example of a flat morphism is a blowup since a flat morphism necessarily has equi-dimensional fibers.

Properties of flat morphisms

Let

f\colonX\toY

be a morphism of schemes. For a morphism

g\colonY'\toY

, let

X'=X x YY'

and

f'=(f,1Y')\colonX'\toY'.

The morphism f is flat if and only if for every g, the pullback

f'*

is an exact functor from the category of quasi-coherent

l{O}Y'

-modules to the category of quasi-coherent

l{O}X'

-modules.[5]

Assume

f\colonX\toY

and

g\colonY\toZ

are morphisms of schemes and f is flat at x in X. Then g is flat at

f(x)

if and only if gf is flat at x.[6] In particular, if f is faithfully flat, then g is flat or faithfully flat if and only if gf is flat or faithfully flat, respectively.[7]

Fundamental properties

g\colonY'\toY

, then the fiber product

f x g\colonX x YY'\toY'

is flat or faithfully flat, respectively.[10]

Suppose

f\colonX\toY

is a flat morphism of schemes.

f*J\tol{O}X

, the pullback of the inclusion map, is an injection, and the image of

f*J

in

l{O}X

is the annihilator of

f*F

on X.[13]

l{O}Y

-module, then the pullback map on global sections

\Gamma(Y,G)\to\Gamma(X,f*G)

is injective.[14]

Suppose

h\colonS'\toS

is flat. Let X and Y be S-schemes, and let

X'

and

Y'

be their base change by h.

f\colonX\toY

is quasi-compact and dominant, then its base change

f'\colonX'\toY'

is quasi-compact and dominant.[15]

\operatorname{Hom}S(X,Y)\to\operatorname{Hom}S'(X',Y')

is injective.[16]

f\colonX\toY

is quasi-compact and quasi-separated. Let Z be the closed image of X, and let

j\colonZ\toY

be the canonical injection. Then the closed subscheme determined by the base change

j'\colonZ'\toY'

is the closed image of

X'

.[17]

Topological properties

If

f\colonX\toY

is flat, then it possesses all of the following properties:

f(\operatorname{Spec}l{O}X,x)=\operatorname{Spec}l{O}Y,f(x)

.[19]

f-1(\barZ)=\overline{f-1(Z)}

.[25]

If f is flat and locally of finite presentation, then f is universally open.[26] However, if f is faithfully flat and quasi-compact, it is not in general true that f is open, even if X and Y are noetherian.[27] Furthermore, no converse to this statement holds: If f is the canonical map from the reduced scheme Xred to X, then f is a universal homeomorphism, but for X non-reduced and noetherian, f is never flat.[28]

If

f\colonX\toY

is faithfully flat, then:

If f is flat and locally of finite presentation, then for each of the following properties P, the set of points where f has P is open:[31]

If in addition f is proper, then the same is true for each of the following properties:[32]

Flatness and dimension

Assume

X

and

Y

are locally noetherian, and let

f\colonX\toY

.

f*F

has projective dimension at most n.[36]

Descent properties

Let be faithfully flat. Let F be a quasi-coherent sheaf on Y, and let F′ be the pullback of F to Y′. Then F is flat over Y if and only if F′ is flat over Y′.[44]

Assume f is faithfully flat and quasi-compact. Let G be a quasi-coherent sheaf on Y, and let F denote its pullback to X. Then F is finite type, finite presentation, or locally free of rank n if and only if G has the corresponding property.[45]

Suppose is an S-morphism of S-schemes. Let be faithfully flat and quasi-compact, and let X′, Y′, and f′ denote the base changes by g. Then for each of the following properties P, if f′ has P, then f has P.[46]

Additionally, for each of the following properties P, f has P if and only if f′ has P.[47]

It is possible for f′ to be a local isomorphism without f being even a local immersion.[48]

If f is quasi-compact and L is an invertible sheaf on X, then L is f-ample or f-very ample if and only if its pullback L′ is f′-ample or f′-very ample, respectively.[49] However, it is not true that f is projective if and only if f′ is projective. It is not even true that if f is proper and f′ is projective, then f is quasi-projective, because it is possible to have an f′-ample sheaf on X′ which does not descend to X.[50]

See also

References

Notes and References

  1. EGA IV2, 2.1.1.
  2. EGA 0I, 6.7.8.
  3. Book: Sernesi, E.. Deformations of Algebraic Schemes. 2010. limited. Springer. 269–279.
  4. Web site: Flat Morphisms and Flatness .
  5. EGA IV2, Proposition 2.1.3.
  6. EGA IV2, Corollaire 2.2.11(iv).
  7. EGA IV2, Corollaire 2.2.13(iii).
  8. EGA IV2, Corollaire 2.1.6.
  9. EGA IV2, Corollaire 2.1.7, and EGA IV2, Corollaire 2.2.13(ii).
  10. EGA IV2, Proposition 2.1.4, and EGA IV2, Corollaire 2.2.13(i).
  11. EGA IV3, Théorème 11.3.1.
  12. EGA IV3, Proposition 11.3.16.
  13. EGA IV2, Proposition 2.1.11.
  14. EGA IV2, Corollaire 2.2.8.
  15. EGA IV2, Proposition 2.3.7(i).
  16. EGA IV2, Corollaire 2.2.16.
  17. EGA IV2, Proposition 2.3.2.
  18. EGA IV2, Proposition 2.3.4(i).
  19. EGA IV2, Proposition 2.3.4(ii).
  20. EGA IV2, Proposition 2.3.4(iii).
  21. EGA IV2, Corollaire 2.3.5(i).
  22. EGA IV2, Corollaire 2.3.5(ii).
  23. EGA IV2, Corollaire 2.3.5(iii).
  24. EGA IV2, Proposition 2.3.6(ii).
  25. EGA IV2, Théorème 2.3.10.
  26. EGA IV2, Théorème 2.4.6.
  27. EGA IV2, Remarques 2.4.8(i).
  28. EGA IV2, Remarques 2.4.8(ii).
  29. EGA IV2, Corollaire 2.3.12.
  30. EGA IV2, Corollaire 2.3.14.
  31. EGA IV3, Théorème 12.1.6.
  32. EGA IV3, Théorème 12.2.4.
  33. EGA IV2, Corollaire 6.1.2.
  34. EGA IV2, Proposition 6.1.5. Note that the regularity assumption on Y is important here. The extension

    \Complex[x2,y2,xy]\subset\Complex[x,y]

    gives a counterexample with X regular, Y normal, f finite surjective but not flat.
  35. EGA IV2, Corollaire 6.1.4.
  36. EGA IV2, Corollaire 6.2.2.
  37. EGA IV2, Proposition 2.1.13.
  38. EGA IV3, Proposition 11.3.13.
  39. EGA IV2, Proposition 2.1.13.
  40. EGA IV2, Proposition 2.1.14.
  41. EGA IV2, Proposition 2.2.14.
  42. EGA IV2, Corollaire 6.5.2.
  43. EGA IV2, Corollaire 6.5.4.
  44. EGA IV2, Proposition 2.5.1.
  45. EGA IV2, Proposition 2.5.2.
  46. EGA IV2, Proposition 2.6.2.
  47. EGA IV2, Corollaire 2.6.4 and Proposition 2.7.1.
  48. EGA IV2, Remarques 2.7.3(iii).
  49. EGA IV2, Corollaire 2.7.2.
  50. EGA IV2, Remarques 2.7.3(ii).