Geometry of the stability scattering diagram for P2 and applications

Abstract

We give a detailed analysis of the stability scattering diagram for P2 introduced by Bousseau. This scattering diagram lives in a subset of R2, and we decompose this subset into three regions, R,R and Runbdd. The region R has a chamber structure whose chambers are in one-to-one correspondence with strong exceptional triples. No ray of the stability scattering diagram enters the interior of such a triangle, replicating a result of Prince, and generalizing a result of Bousseau. The region R is decomposed into diamonds, which are in one-to-one correspondence with exceptional bundles. Each diamond has a vertical diagonal corresponding to a rank zero object and is traversed by a dense set of rays. Crucially, however, there are no collisions of rays inside diamonds, making it still possible to control the scattering diagram in R. Finally, the behaviour of Runbdd is chaotic, in that every rational point inside it is a collision of an infinite number of rays. We show that the bounded region Rbdd= R R has as upper boundary the Le Potier curve, thus showing that this curve arises naturally through the algorithmic scattering process. We give an application of these results by describing the first wall-crossing for the moduli space of one-dimensional rank zero objects on P2. In the sequel, we apply these results to describe the full Bridgeland wall-crossing for Hilbn(P2) for any n.

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