In algebra, flat modules include free modules, projective modules, and, over a principal ideal domain, torsion-free modules. Formally, a module M over a ring R is flat if taking the tensor product over R with M preserves exact sequences. A module is faithfully flat if taking the tensor product with a sequence produces an exact sequence if and only if the original sequence is exact.
Flatness was introduced by in his paper Géometrie Algébrique et Géométrie Analytique.
\varphi:K\toL
\varphi ⊗ RM:K ⊗ RM\toL ⊗ RM
\varphi ⊗ RM
k ⊗ m\mapsto\varphi(k) ⊗ m.
For this definition, it is enough to restrict the injections
\varphi
Equivalently, an -module is flat if the tensor product with is an exact functor; that is if, for every short exact sequence of -modules
0 → K → L → J → 0,
0 → K ⊗ RM → L ⊗ RM → J ⊗ RM → 0
These definitions apply also if is a non-commutative ring, and is a left -module; in this case,, and must be right -modules, and the tensor products are not -modules in general, but only abelian groups.
Flatness can also be characterized by the following equational condition, which means that -linear relations in stem from linear relations in .
A left -module is flat if and only if, for every linear relation
with
ri\inR
xi\inM
yj\inM
ai,j\inR,
for
j=1,\ldots,n,
for
i=1,\ldots,m.
It is equivalent to define elements of a module, and a linear map from
Rn
Rn
An -module is flat if and only if the following condition holds: for every map
f:F\toM,
F
K
\kerf,
f
G
g(K)=0:
Flatness is related to various other module properties, such as being free, projective, or torsion-free. In particular, every flat module is torsion-free, every projective module is flat, and every free module is projective.
There are finitely generated modules that are flat and not projective. However, finitely generated flat modules are all projective over the rings that are most commonly considered. Moreover, a finitely generated module is flat if and only it is locally free, meaning all the localizations at prime ideals are free modules.
This is partly summarized in the following graphic.
Every flat module is torsion-free. This results from the above characterization in terms of relations by taking .
The converse holds over the integers, and more generally over principal ideal domains and Dedekind rings.
An integral domain over which every torsion-free module is flat is called a Prüfer domain.
A module is projective if and only if there is a free module and two linear maps
i:M\toG
p:G\toM
p\circi=idM.
G=M
Every projective module is flat. This can be proven from the above characterizations of flatness and projectivity in terms of linear maps by taking
g=i\circf
h=p.
Conversely, finitely generated flat modules are projective under mild conditions that are generally satisfied in commutative algebra and algebraic geometry. This makes the concept of flatness useful mainly for modules that are not finitely generated.
A finitely presented module (that is the quotient of a finitely generated free module by a finitely generated submodule) that is flat is always projective. This can be proven by taking surjective and
K=\kerf
g(K)=0
i:M\toG
i\circf=g,
h\circi\circf=h\circg=f.
h\circi=idM,
Over a Noetherian ring, every finitely generated flat module is projective, since every finitely generated module is finitely presented. The same result is true over an integral domain, even if it is not Noetherian.
On a local ring every finitely generated flat module is free.
A finitely generated flat module that is not projective can be built as follows. Let
R=FN
R/I,
R/I
R/I
I
\Q/\Z
\Z
\Z
\Q
styleoplusiMi
Mi
A direct limit of flat is flat. In particular, a direct limit of free modules is flat. Conversely, every flat module can be written as a direct limit of finitely-generated free modules.
Direct products of flat modules need not in general be flat. In fact, given a ring, every direct product of flat -modules is flat if and only if is a coherent ring (that is, every finitely generated ideal is finitely presented).
R\toS
S
R
S-1R
\Q
\Z.
If
I
R,
\widehat{R}
R
I
I
A.
In this section, denotes a commutative ring. If
akp
akp
akp
Rakp=(R\setminusakp)-1R,
Makp=(R\setminusakp)-1M=Rakp ⊗ RM.
If is an -module the three following conditions are equivalent:
M
R
Makp
Rakp
akp;
Makm
Rakm
akm.
This property is fundamental in commutative algebra and algebraic geometry, since it reduces the study of flatness to the case of local rings. They are often expressed by saying that flatness is a local property.
The definition of a flat morphism of schemes results immediately from the local property of flatness.
A morphism
f:X\toY
lOY,\tolOX,x
Thus, properties of flat (or faithfully flat) ring homomorphisms extends naturally to geometric properties of flat morphisms in algebraic geometry. For example, consider the flat
C[t]
R=C[t,x,y]/(xy-t)
C[t]\hookrightarrowR
\pi:\operatorname{Spec}(R)\to\operatorname{Spec}(C[t]).
\pi-1(t)
xy=t.
Let
S=R[x1,...,xr]
R
f\inS
S/fS
R
f
C[t,x,y]/(xy-t),
C[t]
A module is faithfully flat if taking the tensor product with a sequence produces an exact sequence if and only if the original sequence is exact. Although the concept is defined for modules over a non-necessary commutative ring, it is used mainly for commutative algebras. So, this is the only case that is considered here, even if some results can be generalized to the case of modules over a non-commutaive ring.
In this section,
f\colonR\toS
S
R
R
S
R
S
R,
f
If
S
R,
S
ak{m}
R
ak{m}S\neS.
M
R
M ⊗ RS\ne0.
ak{p}
R,
ak{P}
S
ak{p}=f-1(akP).
f*\colon\operatorname{Spec}(S)\to\operatorname{Spec}(R)
f
f,
R
S;
M\toM ⊗ RS
R
M
The second condition implies that a flat local homomorphism of local rings is faithfully flat. It follows from the last condition that
I=IS\capR
I
R
M=R/I
S
R
The last but one condition can be stated in the following strengthened form:
\operatorname{Spec}(S)\to\operatorname{Spec}(R)
\operatorname{Spec}(R)
\operatorname{Spec}(S)
R\toS
S
p\inR[x]
R\hookrightarrowR[t]/\langlep\rangle
t1,\ldots,tk\inR.
style\prodi
| -1 | |
| R[t | |
| i |
]
ti
R
t1,\ldots,tk
R
1
ti
Rakp
R
The two last examples are implicitly behind the wide use of localization in commutative algebra and algebraic geometry.
f:A\toB,
\deltan
\delta0(b)=b ⊗ 1-1 ⊗ b
f
Here is one characterization of a faithfully flat homomorphism for a not-necessarily-flat homomorphism. Given an injective local homomorphism
(R,akm)\hookrightarrow(S,akn)
ak{m}S
ak{n}
S\toB
akm
akq
R
\operatorname{length}S(S/akqS)=\operatorname{length}S(S/ak{m}S)\operatorname{length}R(R/akq).
Flatness may also be expressed using the Tor functors, the left derived functors of the tensor product. A left
R
M
| R | |
| \operatorname{Tor} | |
| n |
(X,M)=0
n\ge1
R
X
| R | |
| \operatorname{Tor} | |
| 1 |
(N,M)=0
R
N
N=R/I
I\subsetR
Using the Tor functor's long exact sequences, one can then easily prove facts about a short exact sequence
0\toA\overset{f}{\longrightarrow}B\overset{g}{\longrightarrow}C\to0
If
A
C
B
B
C
A
A
B
C
A
B
B
A
C
A flat resolution of a module
M
… \toF2\toF1\toF0\toM\to0,
Fi
The length of a finite flat resolution is the first subscript n such that
Fn
Fi=0
i>n
M
M
\operatorname{fd}(M)
M
M
\operatorname{fd}(M)=0
0\toF0\toM\to0
M
In some areas of module theory, a flat resolution must satisfy the additional requirement that each map is a flat pre-cover of the kernel of the map to the right. For projective resolutions, this condition is almost invisible: a projective pre-cover is simply an epimorphism from a projective module. These ideas are inspired from Auslander's work in approximations. These ideas are also familiar from the more common notion of minimal projective resolutions, where each map is required to be a projective cover of the kernel of the map to the right. However, projective covers need not exist in general, so minimal projective resolutions are only of limited use over rings like the integers.
While projective covers for modules do not always exist, it was speculated that for general rings, every module would have a flat cover, that is, every module M would be the epimorphic image of a flat module F such that every map from a flat module onto M factors through F, and any endomorphism of F over M is an automorphism. This flat cover conjecture was explicitly first stated in . The conjecture turned out to be true, resolved positively and proved simultaneously by L. Bican, R. El Bashir and E. Enochs. This was preceded by important contributions by P. Eklof, J. Trlifaj and J. Xu.
Since flat covers exist for all modules over all rings, minimal flat resolutions can take the place of minimal projective resolutions in many circumstances. The measurement of the departure of flat resolutions from projective resolutions is called relative homological algebra, and is covered in classics such as and in more recent works focussing on flat resolutions such as .
Flat modules have increased importance in constructive mathematics, where projective modules are less useful. For example, that all free modules are projective is equivalent to the full axiom of choice, so theorems about projective modules, even if proved constructively, do not necessarily apply to free modules. In contrast, no choice is needed to prove that free modules are flat, so theorems about flat modules can still apply.