Stability conditions and canonical metrics

TL;DR

This thesis explores the link between stability conditions and the existence of canonical metrics in differential and algebraic geometry, introducing new concepts like Z-critical metrics and studying their properties and related stability notions.

Contribution

It introduces the concept of Z-critical metrics, establishes a correspondence with stability conditions, and studies optimal symplectic connections and their relation to Hermite-Einstein metrics.

Findings

Proved a correspondence between Z-critical metrics and Bridgeland stability in the large volume limit.

Identified analogues of Donaldson and Yang-Mills functionals for Z-critical equations.

Established a link between optimal symplectic connections and Hermite-Einstein metrics.

Abstract

In this thesis we study the principle that extremal objects in differential geometry correspond to stable objects in algebraic geometry. In our introduction we survey the most famous instances of this principle with a view towards the results and background needed in the later chapters. In Part I we discuss the notion of a $Z$-critical metric recently introduced in joint work with Ruadha\'i Dervan and Lars Martin Sektnan. We prove a correspondence for existence with an analogue of Bridgeland stability in the large volume limit, and study important properties of the subsolution condition away from this limit, including identifying the analogues of the Donaldson and Yang-Mills functionals for the equation. In Part II we study the recent theory of optimal symplectic connections on K\"ahler fibrations in the isotrivial case. We prove a correspondence with the existence of Hermite-Einstein metrics on holomorphic principal bundles.