Holomorphic field theories and higher algebra

TL;DR

This survey explores higher-dimensional holomorphic field theories, their moduli spaces, and their connections to higher algebraic structures like factorization algebras, with implications for complex geometry and dualities.

Contribution

It introduces a systematic framework for quantizing holomorphic moduli spaces using higher algebraic structures and relates these to dualities in algebraic geometry.

Findings

Holomorphic field theories generate examples of higher algebraic structures.

Frameworks for quantizing moduli spaces via factorization algebras are developed.

Seiberg duality predicts relationships between holomorphic gauge theories and algebraic dualities.

Abstract

Aimed at complex geometers and representation theorists, this survey explores higher dimensional analogues of the rich interplay between Riemann surfaces, Virasoro and Kac-Moody Lie algebras, and conformal blocks. We introduce a panoply of examples from physics -- field theories that are holomorphic in nature, such as holomorphic Chern-Simons theory -- and interpret them as (derived) moduli spaces in complex geometry; no comfort with physics is presumed. We then describe frameworks for quantizing such moduli spaces, offering a systematic generalization of vertex algebras and conformal blocks via factorization algebras, and we explain how holomorphic field theories generate examples of these higher algebraic structures. We finish by describing how the conjecture of Seiberg duality predicts a surprising relationship between holomorphic gauge theories on algebraic surfaces and how it suggests analogues of the Hori-Tong dualities already studied by algebraic geometers.