Convexity (algebraic geometry) explained
In algebraic geometry, convexity is a restrictive technical condition for algebraic varieties originally introduced to analyze Kontsevich moduli spaces
in
quantum cohomology.
[1] [2] [3] These moduli spaces are smooth
orbifolds whenever the target space is convex. A variety
is called convex if the pullback of the tangent bundle to a stable
rational curve
has globally generated sections. Geometrically this implies the curve is free to move around
infinitesimally without any obstruction. Convexity is generally phrased as the technical condition
since Serre's vanishing theorem guarantees this sheaf has globally generated sections. Intuitively this means that on a neighborhood of a point, with a vector field in that neighborhood, the local parallel transport can be extended globally. This generalizes the idea of convexity in Euclidean geometry, where given two points
in a convex set
, all of the points
are contained in that set. There is a vector field
in a neighborhood
of
transporting
to each point
p'\in\{tp+(1-t)q:t\in[0,1]\}\capUp
. Since the vector bundle of
is trivial, hence globally generated, there is a vector field
on
such that the equality
holds on restriction.
Examples
There are many examples of convex spaces, including the following.
Spaces with trivial rational curves
If the only maps from a rational curve to
are constants maps, then the pullback of the tangent sheaf is the free sheaf
where
. These sheaves have trivial non-zero cohomology, and hence they are always convex. In particular,
Abelian varieties have this property since the
Albanese variety of a rational curve
is trivial, and every map from a variety to an Abelian variety factors through the Albanese.
[4] Projective spaces
Projective spaces are examples of homogeneous spaces, but their convexity can also be proved using a sheaf cohomology computation. Recall the Euler sequence relates the tangent space through a short exact sequence
0\tol{O}\tol{O}(1) ⊕ \to
\to0
If we only need to consider degree
embeddings, there is a short exact sequence
giving the long exact sequence
\begin{align}
0&\toH0(C,l{O})\toH0(C,l{O}(d) ⊕ (n+1))\toH0(C,f
)\\
&\toH1(C,l{O})\toH1(C,l{O}(d) ⊕ (n+1))\toH1(C,f
)\to0
\end{align}
since the first two
-terms are zero, which follows from
being of genus
, and the second calculation follows from the
Riemann–Roch theorem, we have convexity of
. Then, any nodal map can be reduced to this case by considering one of the components
of
.
Homogeneous spaces
Another large class of examples are homogenous spaces
where
is a parabolic subgroup of
. These have globally generated sections since
acts transitively on
, meaning it can take a bases in
to a basis in any other point
, hence it has globally generated sections. Then, the pullback is always globally generated. This class of examples includes
Grassmannians, projective spaces, and
flag varieties.
Product spaces
Also, products of convex spaces are still convex. This follows from the Künneth theorem in coherent sheaf cohomology.
Projective bundles over curves
One more non-trivial class of examples of convex varieties are projective bundles
for an algebraic vector bundle
over a smooth algebraic curve
pg 6.
Applications
There are many useful technical advantages of considering moduli spaces of stable curves mapping to convex spaces. That is, the Kontsevich moduli spaces
have nice geometric and deformation-theoretic properties.
Deformation theory
The deformations of
in the Hilbert scheme of graphs
\operatorname{Hom}(C,X)\subset\operatorname{Hilb}C x (C)}
has tangent space
T\operatorname{Hom(C,X)}([f])\congH0(C,
where
[f]\in\operatorname{Hom}(C,X)
is the point in the scheme representing the map. Convexity of
gives the dimension formula below. In addition, convexity implies all infinitesimal deformations are unobstructed.
[5] Structure
These spaces are normal projective varieties of pure dimension
\dim(\overline{M}0,n(X,\beta))=\dim(X)+\int\betac1(TX)+n-3
which are locally the quotient of a smooth variety by a finite group. Also, the open subvariety
| *(X,\beta) |
| \overline{M} | |
| 0,n |
parameterizing non-singular maps is a smooth fine moduli space. In particular, this implies the stacks
\overline{l{M}}0,n(X,\beta)
are
orbifolds.
Boundary divisors
The moduli spaces
have nice boundary divisors for convex varieties
given by
D(A,B;\beta1,\beta2)=\overline{M}0,A\cup
}(X,\beta_1) \times_X \overline_(X,\beta_2)
for a partition
of
and
the point lying along the
intersection of two rational curves
.
See also
External links
Notes and References
- Kontsevich. Maxim. Maxim Kontsevich . Enumeration of Rational Curves Via Torus Actions. 1995. The Moduli Space of Curves. Progress in Mathematics. 129. 335–368. Dijkgraaf. Robbert H.. Robbert Dijkgraaf . Birkhäuser. Boston. en. 10.1007/978-1-4612-4264-2_12. 978-1-4612-8714-8. Faber. Carel F.. van der Geer. Gerard B. M.. hep-th/9405035. 16131978.
- Web site: Gromov-Witten Classes, Quantum Cohomology, and Enumerative Geometry. Kontsevich. Maxim. Manin. Yuri. Maxim Kontsevich . Yuri Manin . 9. live. https://web.archive.org/web/20091128014639/http://www.ihes.fr:80/~maxim/TEXTS/WithManinCohFT.pdf . 2009-11-28 .
- Fulton. W.. Pandharipande. R.. 1997-05-17. Notes on stable maps and quantum cohomology. alg-geom/9608011. 6,12,29,31.
- Web site: ag.algebraic geometry - Is there any rational curve on an Abelian variety?. MathOverflow. 2020-02-28.
- Web site: Lectures on Donaldson-Thomas Theory. Maulik. Davesh. 2. live. https://web.archive.org/web/20200301003013/https://www-fourier.ujf-grenoble.fr/sites/ifmaquette.ujf-grenoble.fr/files/ete2011-maulik.pdf . 2020-03-01 .
