Positive current

In mathematics, more particularly in complex geometry, algebraic geometry and complex analysis, a positive current is a positive (n-p,n-p)-form over an n-dimensional complex manifold, taking values in distributions.

For a formal definition, consider a manifold M. Currents on M are (by definition) differential forms with coefficients in distributions; integrating over M, we may consider currents as "currents of integration", that is, functionals

${\displaystyle \eta \mapsto \underset{M}{\int }\eta \wedge \rho }$

on smooth forms with compact support. This way, currents are considered as elements in the dual space to the space ${\displaystyle {\mathrm{\Lambda }}_c^{*}(M)}$ of forms with compact support.

Now, let M be a complex manifold. The Hodge decomposition ${\displaystyle {\mathrm{\Lambda }}^i(M)=\underset{p+q=i}{⨁}{\mathrm{\Lambda }}^{p,q}(M)}$ is defined on currents, in a natural way, the (p,q)-currents being functionals on ${\displaystyle {\mathrm{\Lambda }}_c^{p,q}(M)}$.

A positive current is defined as a real current of Hodge type (p,p), taking non-negative values on all positive (p,p)-forms.

Using the Hahn–Banach theorem, Harvey and Lawson proved the following criterion of existence of Kähler metrics.^[1]

Theorem: Let M be a compact complex manifold. Then M does not admit a Kähler structure if and only if M admits a non-zero positive (1,1)-current ${\displaystyle \mathrm{\Theta }}$ which is a (1,1)-part of an exact 2-current.

Note that the de Rham differential maps 3-currents to 2-currents, hence ${\displaystyle \mathrm{\Theta }}$ is a differential of a 3-current; if ${\displaystyle \mathrm{\Theta }}$ is a current of integration of a complex curve, this means that this curve is a (1,1)-part of a boundary.

When M admits a surjective map ${\displaystyle \pi :M\mapsto X}$ to a Kähler manifold with 1-dimensional fibers, this theorem leads to the following result of complex algebraic geometry.

Corollary: In this situation, M is non-Kähler if and only if the homology class of a generic fiber of ${\displaystyle \pi }$ is a (1,1)-part of a boundary.

• P. Griffiths and J. Harris (1978), Principles of Algebraic Geometry, Wiley. Template:Isbn
• J.-P. Demailly, $L^2$ vanishing theorems for positive line bundles and adjunction theory, Lecture Notes of a CIME course on "Transcendental Methods of Algebraic Geometry" (Cetraro, Italy, July 1994)