Logarithmic form

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In contexts including complex manifolds and algebraic geometry, a logarithmic differential form is a meromorphic differential form with poles of a certain kind.

Let X be a complex manifold, and DX a divisor and ω a holomorphic p-form on XD. If ω and dω have a pole of order at most one along D, then ω is said to have a logarithmic pole along D. ω is also known as a logarithmic p-form. The logarithmic p-forms make up a subsheaf of the meromorphic p-forms on X with a pole along D, denoted

\Omega _{X}^{p}(\log D).

In the theory of Riemann surfaces, one encounters logarithmic one-forms which have the local expression

\omega ={\frac  {df}{f}}=\left({\frac  {m}{z}}+{\frac  {g'(z)}{g(z)}}\right)dz

for some meromorphic function (resp. rational function) f(z)=z^{m}g(z), where g is holomorphic and non-vanishing at 0, and m is the order of f at 0.. That is, for some open covering, there are local representations of this differential form as a logarithmic derivative (modified slightly with the exterior derivative d in place of the usual differential operator d/dz). Observe that ω has only simple poles with integer residues. On higher dimensional complex manifolds, the Poincaré residue is used to describe the distinctive behavior of logarithmic forms along poles.

Holomorphic Log Complex

By definition of \Omega _{X}^{p}(\log D) and the fact that exterior differentiation d satisfies d2 = 0, one has

d\Omega _{X}^{p}(\log D)(U)\subset \Omega _{X}^{{p+1}}(\log D)(U).

This implies that there is a complex of sheaves (\Omega _{X}^{{\bullet }}(\log D),d), known as the holomorphic log complex corresponding to the divisor D. This is a subcomplex of j_{*}\Omega _{{X-D}}^{{\bullet }}, where j:X-D\rightarrow X is the inclusion and \Omega _{{X-D}}^{{\bullet }} is the complex of sheaves of holomorphic forms on XD.

Of special interest is the case where D has simple normal crossings. Then if \{D_{{\nu }}\} are the smooth, irreducible components of D, one has D=\sum D_{{\nu }} with the D_{{\nu }} meeting transversely. Locally D is the union of hyperplanes, with local defining equations of the form z_{1}\cdots z_{k}=0 in some holomorphic coordinates. One can show that the stalk of \Omega _{X}^{1}(\log D) at p satisfies[1]

\Omega _{X}^{1}(\log D)_{p}={\mathcal  {O}}_{{X,p}}{\frac  {dz_{1}}{z_{1}}}\oplus \cdots \oplus {\mathcal  {O}}_{{X,p}}{\frac  {dz_{k}}{z_{k}}}\oplus {\mathcal  {O}}_{{X,p}}dz_{{k+1}}\oplus \cdots \oplus {\mathcal  {O}}_{{X,p}}dz_{n}

and that

\Omega _{X}^{k}(\log D)_{p}=\bigwedge _{{j=1}}^{k}\Omega _{X}^{1}(\log D)_{p}.

Some authors, e.g.,[2] use the term log complex to refer to the holomorphic log complex corresponding to a divisor with normal crossings.

Higher Dimensional Example

Consider a once-punctured elliptic curve, given as the locus D of complex points (x,y) satisfying g(x,y)=y^{2}-f(x)=0, where f(x)=x(x-1)(x-\lambda ) and \lambda \neq 0,1 is a complex number. Then D is a smooth irreducible hypersurface in C2 and, in particular, a divisor with simple normal crossings. There is a meromorphic two-form on C2

\omega ={\frac  {dx\wedge dy}{g(x,y)}}

which has a simple pole along D. The Poincaré residue [2] of ω along D is given by the holomorphic one-form

{\text{Res}}_{D}(\omega )={\frac  {dy}{\partial g/\partial x}}|_{D}=-{\frac  {dx}{\partial g/\partial y}}|_{D}=-{\frac  {1}{2}}{\frac  {dx}{y}}|_{D}.

Vital to the residue theory of logarithmic forms is the Gysin sequence, which is in some sense a generalization of the Residue Theorem for compact Riemann surfaces. This can be used to show, for example, that dx/y|_{D} extends to a holomorphic one-form on the projective closure of D in P2, a smooth elliptic curve.

Hodge Theory

The holomorphic log complex can be brought to bear on the Hodge theory of complex algebraic varieties. Let X be a complex algebraic manifold and j:X\hookrightarrow Y a good compactification. This means that Y is a compact algebraic manifold and D = YX is a divisor on Y with simple normal crossings. The natural inclusion of complexes of sheaves

\Omega _{Y}^{{\bullet }}(\log D)\rightarrow j_{*}\Omega _{{X}}^{{\bullet }}

turns out to be a quasi-isomorphism. Thus

H^{k}(X;{\mathbf  {C}})={\mathbb  {H}}^{k}(Y,\Omega _{Y}^{{\bullet }}(\log D))

where {\mathbb  {H}}^{{\bullet }} denotes hypercohomology of a complex of abelian sheaves. There is[1] a decreasing filtration W_{{\bullet }}\Omega _{Y}^{p}(\log D) given by

W_{{m}}\Omega _{Y}^{p}(\log D)={\begin{cases}0&m<0\\\Omega _{Y}^{p}(\log D)&m\geq p\\\Omega _{Y}^{{p-m}}\wedge \Omega _{Y}^{m}(\log D)&0\leq m\leq p\end{cases}}

which, along with the trivial increasing filtration F^{{\bullet }}\Omega _{Y}^{p}(\log D) on logarithmic p-forms, produces filtrations on cohomology

W_{m}H^{k}(X;{\mathbf  {C}})={\text{Im}}({\mathbb  {H}}^{k}(Y,W_{{m-k}}\Omega _{Y}^{{\bullet }}(\log D))\rightarrow H^{k}(X;{\mathbf  {C}}))
F^{p}H^{k}(X;{\mathbf  {C}})={\text{Im}}({\mathbb  {H}}^{k}(Y,F^{p}\Omega _{Y}^{{\bullet }}(\log D))\rightarrow H^{k}(X;{\mathbf  {C}})).

One shows[1] that W_{m}H^{k}(X;{\mathbf  {C}}) can actually be defined over Q. Then the filtrations W_{{\bullet }},F^{{\bullet }} on cohomology give rise to a mixed Hodge structure on H^{k}(X;{\mathbf  {Z}}).

Classically, for example in elliptic function theory, the logarithmic differential forms were recognised as complementary to the differentials of the first kind. They were sometimes called differentials of the second kind (and, with an unfortunate inconsistency, also sometimes of the third kind). The classical theory has now been subsumed as an aspect of Hodge theory. For a Riemann surface S, for example, the differentials of the first kind account for the term H1,0 in H1(S), when by the Dolbeault isomorphism it is interpreted as the sheaf cohomology group H0(S,Ω); this is tautologous considering their definition. The H1,0 direct summand in H1(S), as well as being interpreted as H1(S,O) where O is the sheaf of holomorphic functions on S, can be identified more concretely with a vector space of logarithmic differentials.

See also

References

  1. 1.0 1.1 1.2 Chris A.M. Peters; Joseph H.M. Steenbrink (2007). Mixed Hodge Structures. Springer. ISBN 978-3-540-77015-6
  2. 2.0 2.1 Phillip A. Griffiths; Joseph Harris (1979). Principles of Algebraic Geometry. Wiley-Interscience. ISBN 0-471-05059-8.
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