In algebraic geometry and the theory of complex manifolds, a logarithmic differential form is a differential form with poles of a certain kind. The concept was introduced by Pierre Deligne.[1] In short, logarithmic differentials have the mildest possible singularities needed in order to give information about an open submanifold (the complement of the divisor of poles). (This idea is made precise by several versions of de Rham's theorem discussed below.)
Let X be a complex manifold, D ⊂ X a reduced divisor (a sum of distinct codimension-1 complex subspaces), and ω a holomorphic p-form on X−D. If both ω and dω have a pole of order at most 1 along D, then ω is said to have a logarithmic pole along D. ω is also known as a logarithmic p-form. The p-forms with log poles along D form a subsheaf of the meromorphic p-forms on X, denoted
| p | |
| \Omega | |
| X(log |
D).
The name comes from the fact that in complex analysis,
d(logz)=dz/z
dz/z
dz/z
Let X be a complex manifold and D a reduced divisor on X. By definition of
| p | |
| \Omega | |
| X(log |
D)
| p | |
| d\Omega | |
| X(log |
D)(U)\subset
| p+1 | |
| \Omega | |
| X(log |
D)(U)
(
| \bullet | |
| \Omega | |
| X(log |
D),d)
| \bullet | |
| j | |
| X-D |
)
j:X-D → X
| \bullet | |
| \Omega | |
| X-D |
Of special interest is the case where D has normal crossings: that is, D is locally a sum of codimension-1 complex submanifolds that intersect transversely. In this case, the sheaf of logarithmic differential forms is the subalgebra of
| \bullet | |
| j | |
| X-D |
)
| \bullet | |
| \Omega | |
| X |
df/f
f
| d(fg) | = | |
| fg |
| df | + | |
| f |
| dg | |
| g |
.
Concretely, if D is a divisor with normal crossings on a complex manifold X, then each point x has an open neighborhood U on which there are holomorphic coordinate functions
z1,\ldots,zn
z1 … zk=0
0\leqk\leqn
| 1 | |
| \Omega | |
| X(log |
D)
| 1(log | |
| \Omega | |
| X |
D)=l{O}X
| dz1 | |
| z1 |
⊕ … ⊕ l{O}X
| dzk | |
| zk |
⊕ l{O}Xdzk+1 ⊕ … ⊕ l{O}Xdzn.
| 1(log | |
| \Omega | |
| X |
D)
X
k\geq0
| k | |
| \Omega | |
| X(log |
D)
| k(log | |
| \Omega | |
| X |
D)=wedgek
| 1(log | |
| \Omega | |
| X |
D).
The logarithmic tangent bundle
TX(-logD)
| 1 | |
| \Omega | |
| X(log |
D)
TX(-logD)
Let X be a complex manifold and D a divisor with normal crossings on X. Deligne proved a holomorphic analog of de Rham's theorem in terms of logarithmic differentials. Namely,
Hk(X,
| \bullet | |
| \Omega | |
| X(log |
D))\congHk(X-D,C),
| \bullet | |
| \Omega | |
| X(log |
D) → j*\Omega
| \bullet | |
| X-D |
In algebraic geometry, the vector bundle of logarithmic differential p-forms
| p | |
| \Omega | |
| X(log |
D)
D=\sumDj
| p | |
| \Omega | |
| X(log |
D)
X-D
Dj
1\lej\lek
Dj
j>k
uj
Dj
uj=0
1\lej\lek
u1= … =un=0
| 1 | |
| \Omega | |
| X(log |
D)
{du1\overu1},...,{duk\overuk},duk+1,...,dun.
| 1 | |
| \Omega | |
| X(log |
D)
| p | |
| \Omega | |
| X(log |
D)
| 1 | |
| \Omega | |
| X(log |
D)
There is an exact sequence of coherent sheaves on X:
0\to
| 1 | |
| \Omega | |
| X |
\to
| 1 | |
| \Omega | |
| X(log |
D)\overset{\beta}\to ⊕ j({ij})*l{O}
| Dj |
\to0,
ij:Dj\toX
0\to
| p | |
| \Omega | |
| X |
\to
| p | |
| \Omega | |
| X(log |
D)\overset{\beta}\to ⊕ j({ij})
| p-1 | |
| Dj |
(log(D-Dj))\to … \to0,
Explicitly, on an open subset of
X
Dj
D
Dj
f=0
p
Dj
| Res | ( | |
| Dj |
| df | |
| f |
\wedge
| \alpha)=\alpha| | |
| Dj |
(p-1)
\alpha
\alpha\wedge(df/f)
| \alpha| | |
| Dj |
(-1)p-1
Over the complex numbers, the residue of a differential form with log poles along a divisor
Dj
X
Dj
P2=\{[x,y,z]\}
z=1
g(x,y)=y2-f(x)=0,
f(x)=x(x-1)(x-λ)
λ ≠ 0,1
P2
P2
\omega=
| dx\wedgedy | |
| g(x,y) |
,
| K | |
| P2 |
| 2 | |
| =\Omega | |
| P2 |
l{O}(-3)
\omega
\omega
\omega
z=0
ResD(\omega)=\left.
| dy | |
| \partialg/\partialx |
\right|D=\left.-
| dx | |
| \partialg/\partialy |
\right|D=\left.-
| 1 | |
| 2 |
| dx | |
| y |
\right|D.
dx/y|D
P2
The residue map
H0(P2,\Omega
| 2 | |
| P2 |
(logD))\toH0(D,\Omega
| 1 | |
| D) |
H2(P2-D,C)\toH1(D,C)
… \toHj-2(D)\toHj(X)\toHj(X-D)\toHj-1(D)\to … .
Λ
| \zeta(z)= | \sigma'(z) |
| \sigma(z) |
.
\zeta(z)dz=d\sigma/\sigma
Λ
Λ
\sigma(z).
Over the complex numbers, Deligne proved a strengthening of Alexander Grothendieck's algebraic de Rham theorem, relating coherent sheaf cohomology with singular cohomology. Namely, for any smooth scheme X over C with a divisor with simple normal crossings D, there is a natural isomorphism
Hk(X,
| \bullet | |
| \Omega | |
| X(log |
D))\congHk(X-D,C)
Moreover, when X is smooth and proper over C, the resulting spectral sequence
| pq | |
| E | |
| 1 |
=Hq(X,\Omega
| p | |
| X(log |
D)) ⇒ Hp+q(X-D,C)
E1
X-D
Hq(X,\Omega
| p | |
| X(log |
D))
This is part of the mixed Hodge structure which Deligne defined on the cohomology of any complex algebraic variety. In particular, there is also a weight filtration on the rational cohomology of
X-D
H*(X-D,C)
W\bullet
| p | |
| \Omega | |
| X(log |
D)
Wm
| p | |
| \Omega | |
| X(log |
D)=\begin{cases} 0&m<
| p-m | |
| 0\\ \Omega | |
| X ⋅ |
| m | |
| \Omega | |
| X(log |
D)&0\leqm\leq
| p | |
| p\\ \Omega | |
| X(log |
D)&m\geqp. \end{cases}
| k(X-D, | |
| W | |
| mH |
C)=Im(Hk(X,Wm-k
| \bullet | |
| \Omega | |
| X(log |
D)) → Hk(X-D,C)).
Building on these results, Hélène Esnault and Eckart Viehweg generalized the Kodaira–Akizuki–Nakano vanishing theorem in terms of logarithmic differentials. Namely, let X be a smooth complex projective variety of dimension n, D a divisor with simple normal crossings on X, and L an ample line bundle on X. Then
Hq(X,\Omega
| p | |
| X(log |
D) ⊗ L)=0
Hq(X,\Omega
| p | |
| X(log |
D) ⊗ OX(-D) ⊗ L)=0
p+q>n