K3 surface: Difference between revisions

In complex geometry and in algebraic geometry ${\displaystyle K3}$ are the 2-dimensional analog of eliptic curves. The complex and algebro-geometric definitions are slightly different, and coincide in the case where the surface is an algebraic ${\displaystyle K3}$ surface over the complex numbers.

The algebro-geometric definition

In algebraic geometry a surface ${\displaystyle S}$ is a ${\displaystyle K3}$ surface if it is smooth, projective, with trivial canonical bundle, and such that ${\displaystyle h^{1}(O_{S})=0}$. In this case one automatically gets: ${\displaystyle h^{2}(O_{S})=1}$.

Examples

• If ${\displaystyle C\subset \mathbb {P} ^{2}}$ is a smooth curve of degree ${\displaystyle 6}$ and ${\displaystyle p:S\to \mathbb {P} ^{1}}$ is the double cover of ${\displaystyle \mathbb {P} ^{2}}$ branched along ${\displaystyle C}$, then ${\displaystyle S}$ ${\displaystyle K3}$ surface; indeed in the Picard group of ${\displaystyle S}$ we have ${\displaystyle K_{S}=p^{*}(K_{\mathbb {P} ^{2}}-{\frac {1}{2}}[C])=p^{*}0=0}$. A similar claim hods even if the curve ${\displaystyle C}$ is singular; the modification is that now one has to consider the normalization of the branch double cover. Specifically if the curve ${\displaystyle C}$ is a six lines tangent to a conic, then on recovers for the double cover model of a Kummer surface.
• A quartic surface in ${\displaystyle \mathbb {P} ^{3}}$
• A complete intersection of a quadric and a cubic hyper-surfaces in ${\displaystyle \mathbb {P} ^{4}}$
• A complete intersection of three quadric hypersurfaces in ${\displaystyle \mathbb {P} ^{5}}$

In the last three examples one may verify that the canonical bundle is trivial using adjunction formula

Polarization

Complex definition

In complex geometry a surface is complete smooth simply connected surface with trivial canonical class.

The Hodge diamond

The period map and the Torelli theorem

Complex algebraic K3 surfaces

Moduli