Heterotic sigma models via formal geometry and BV quantization

Ladouce, James

07 October 2021

Nonlinear sigma-models in physics have been a source of interesting and important ideas in geometry, topology, and algebra. One such model is the curved beta gamma system. This purely bosonic model studies maps from a Riemann surface to a target complex manifold X. The solutions to the classical equations of motion are holomorphic maps. An extension of this model - the so-called heterotic model, incorporates fermionic fields valued in a holomorphic vector bundle E on the complex manifold. In this thesis, I study this extended model within the framework of effective field theory and BV quantization developed by Kevin Costello. Building on earlier work of Gorbounov-Gwilliam-Williams in the purely bosonic case, my approach uses tools of Gelfand-Kazhdan formal geometry and derived deformation theory to extract obstructions to quantization (anomalies) and identify these with characteristic classes of the target manifold. Specifically, I show that the obstruction to solving the Quantum Master Equation can be identified with the class ch_2 (TX)-ch_2(E), and the obstruction to the quantizing equivariantly with respect to holomorphic vector fields on the source Riemann surface can be identified with c_1 (TX) - c_1(E). By analyzing the theory where the source is an elliptic curve, an explicit geometric construction of the partition function is given.

Mathematics

Anomaly

BC beta gamma system

BV quantization

Formal geometry

Heterotic sigma model

Supersymmetry