Kummer surface: Difference between revisions

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Since <math>p</math> is a simple node, the tangent cone to this point is mapped to a conic under the double cover. This conic is in fact tangent to the six lines (w.o proof). Conversely, given a configuration of a conic and six lines which tangent to it in the plane, we may define the double cover of the plane ramified over the union of these 6 lines. This double cover may be mapped to <mathbb>\mathbb{P}^3</math>, under a map which [[blow down|blows down]] the doubel cover of the special conic, and is an isomorphism elsewhere (w.o. proof).
Since <math>p</math> is a simple node, the tangent cone to this point is mapped to a conic under the double cover. This conic is in fact tangent to the six lines (w.o proof). Conversely, given a configuration of a conic and six lines which tangent to it in the plane, we may define the double cover of the plane ramified over the union of these 6 lines. This double cover may be mapped to <mathbb>\mathbb{P}^3</math>, under a map which [[blow down|blows down]] the doubel cover of the special conic, and is an isomorphism elsewhere (w.o. proof).


=== Kummers's quartic surfaces and kummer varieties of Jacobians ===
=== The double plane and Kummer varieties of Jacobians ===
Starting from a smooth curve <math>C</math> of genus 2, we may identify the Jacobian <math>Jac(C)</math>
with <math>Pic^2(C)</math> under the map <math>x\mapsto x+K_C</math>. We now observe two facts: Since <math>C</math> is a [[hyperelliptic curve]] the map from the symmetric product
<math>Sym^2 C</math> to <math>Pic^2 C</math>, defined by <math>\{p,q\}\mapsto p+q</math>, is the blow up along the [[canonical divisor]]. Moreover, the canonical map <math>C\to|K_C|^*</math> is a double cover. Hence we get a double cover <math>Kum(C)\to Sym^2|K_C|^*</math>. This double cover is the double cover which appeared above, where the 6 lines are the images of the odd symmetric [[theta divisors]] on <math>Jac(C)</math>, while the conic is the image of the blown-up 0. Both the conic, and each of the six lines is an image of the canonical system of <math>C</math>. There is a 1-1 correspondence between pairs of odd symmetric theta divisors and 2-torsion points on the Jacobian given by the fact that <math>(\Theta+w_1)\cap(\Theta+w_2)=\{w_1-w_2,0\}</math>, where <math>w_1,w_2</math> are Weierstrass points  (which are the odd theta characteritics in this cae). Hence the branch points of the canonical map <math>C\mapsto |K_C|^*</math> appear on each of these copies of the canonical system as the intersection points of the lines and the tangency points of the lines and the conic.


=== The quadric line complex ===
=== The quadric line complex ===

Revision as of 18:45, 9 March 2007

In algebraic geometry, Kummer's quartic surface is an irreducible algebraic surface over a field of characteristic different then 2, which is a hypersurface of degree 4 in with 16 singularities; the maximal possible number of singularities of a quartic surface. It is a remarkable fact that any such surface is the Kummer variety of the Jacobian of a smooth hyperelliptic curve of genus 2; i.e. a quotient of the Jacobian by the Kummer involution . The Kummer involution has 16 fixed points: the 16 2-torsion point of the Jacobian, and they are the 16 singular points of the quartic surface.

Geometry of the Kummer surface

Singular quartic surfaces and the double plane model

Let be a quartic surface, and let be a singular point of this surface. Identifying the lines in thorugh the point with , we get a double cover from the blow up of at to ; this double cover is given by sending , and any line in the tangent cone of in to itself. The ramification locus of the double cover is a plane curve of degree 6, and all the nodes of which are not map to nodes of .

By the genus degree formula, the maximal number possible number of nodes on a sextic curve is obtained when the curve is a a union of lines, in which case we have 15 nodes. Hence the maximal number of nodes on a quartic is 16, and in this case they are all simple nodes (to show that is simple project from another node). A quartic which obtains these 16 nodes is called a Kummer Quartic, and we will concentrate on them below.

Since is a simple node, the tangent cone to this point is mapped to a conic under the double cover. This conic is in fact tangent to the six lines (w.o proof). Conversely, given a configuration of a conic and six lines which tangent to it in the plane, we may define the double cover of the plane ramified over the union of these 6 lines. This double cover may be mapped to <mathbb>\mathbb{P}^3</math>, under a map which blows down the doubel cover of the special conic, and is an isomorphism elsewhere (w.o. proof).

The double plane and Kummer varieties of Jacobians

Starting from a smooth curve of genus 2, we may identify the Jacobian with under the map . We now observe two facts: Since is a hyperelliptic curve the map from the symmetric product to , defined by , is the blow up along the canonical divisor. Moreover, the canonical map is a double cover. Hence we get a double cover . This double cover is the double cover which appeared above, where the 6 lines are the images of the odd symmetric theta divisors on , while the conic is the image of the blown-up 0. Both the conic, and each of the six lines is an image of the canonical system of . There is a 1-1 correspondence between pairs of odd symmetric theta divisors and 2-torsion points on the Jacobian given by the fact that , where are Weierstrass points (which are the odd theta characteritics in this cae). Hence the branch points of the canonical map appear on each of these copies of the canonical system as the intersection points of the lines and the tangency points of the lines and the conic.

The quadric line complex

Geometry and combinatorics of the level structure

Polar lines

Apolar complexes

Klien's configuration

Kummer's configurations

fundamental quadrics

fundamental tetrahedra

Rosenheim tetrads

Gopel tetrads

References

  • Igor Dolgachev's online notes on classical algebraic geometry (this is the main source of the first part of this article)