Strong semistability/Arithmetic and geometric deformations/description

Let ${\displaystyle C\to \mathrm{Spec}D}$ be a smooth projective relative curve, where ${\displaystyle D}$ is a domain. A vector bundle ${\displaystyle 𝒮}$ over ${\displaystyle C}$ induces on every fiber a vector bundle. If ${\displaystyle 𝒮}$ is semistable in the generic fiber, then it is also semistable for the fibers over a non-empty open set of ${\displaystyle \mathrm{Spec}D}$. What can we say about strong semistability?

We have to distinguish two forms of deformations:

• Arithmetic deformations: ${\displaystyle D}$ contains ${\displaystyle \mathbb{Z}}$. Here the generic fiber is in characteristic zero, and suppose the bundle is semistable on the generic fiber. What can we say about strong semistability on the special fibers?

A problem of Miyaoka (85) asks in this setting (for ${\displaystyle D}$ of dimension one): does there exist infinitely many closed points ${\displaystyle 𝔭}$ in ${\displaystyle \mathrm{Spec}D}$ such that ${\displaystyle {𝒮}_{𝔭}}$ is strongly semistable on ${\displaystyle C_{𝔭}}$?

This is still open, but the stronger question whether for almost all closed points the restricition is strongly semistable (asked by Shepherd-Barron) has a negative answer.

• Geometric deformations: ${\displaystyle D}$ contains ${\displaystyle \mathbb{Z}/(p)}$. Here suppose that the bundle on the generic fiber is strongly semistable. Then ${\displaystyle F^{e*}(𝒮)}$ makes sense everywhere and it is semistable on the fibers over an open subset ${\displaystyle U_e\subseteq \mathrm{Spec}D}$, however this subset depends on ${\displaystyle e}$ and the intersection might become smaller and smaller.

In retrospective, Paul Monsky provided for both questions counter-examples. His results were formulated in terms of Hilbert-Kunz multiplicity, but this can be translated to strong semistability by work of Brenner and Trivedi.