Universal structures in $\mathbb C$-linear enumerative invariant theories
Abstract
An enumerative invariant theory in Algebraic Geometry, Differential Geometry, or Representation Theory, is the study of invariants which 'count' -(semi)stable objects with fixed topological invariants in some geometric problem, using a virtual class in some homology theory for the moduli spaces of -(semi)stable objects. Examples include Mochizuki's invariants counting coherent sheaves on surfaces, Donaldson-Thomas type invariants counting coherent sheaves on Calabi-Yau 3- and 4-folds and Fano 3-folds, and Donaldson invariants of 4-manifolds. We make conjectures on new universal structures common to many enumerative invariant theories. Such theories have two moduli spaces , where the second author gives the structure of a graded vertex algebra, and a graded Lie algebra, closely related to . The virtual classes take values in . Defining when (in gauge theory, when the moduli space contains reducibles) is a difficult problem. We conjecture that there is a natural way to define in homology over , and that the resulting classes satisfy a universal wall-crossing formula under change of stability condition , written using the Lie bracket on . We prove our conjectures for moduli spaces of representations of quivers without oriented cycles. Our conjectures in Algebraic Geometry using Behrend-Fantechi virtual classes are proved in the sequel arXiv:2111.04694.
Cite
@article{arxiv.2005.05637,
title = {Universal structures in $\mathbb C$-linear enumerative invariant theories},
author = {Jacob Gross and Dominic Joyce and Yuuji Tanaka},
journal= {arXiv preprint arXiv:2005.05637},
year = {2022}
}