Superconformal Blocks: General Theory
Abstract
In this work we launch a systematic theory of superconformal blocks for four-point functions of arbitrary supermultiplets. Our results apply to a large class of superconformal field theories including 4-dimensional models with any number of supersymmetries. The central new ingredient is a universal construction of the relevant Casimir differential equations. In order to find these equations, we model superconformal blocks as functions on the supergroup and pick a distinguished set of coordinates. The latter are chosen so that the superconformal Casimir operator can be written as a perturbation of the Casimir operator for spinning bosonic blocks by a fermionic (nilpotent) term. Solutions to the associated eigenvalue problem can be obtained through a quantum mechanical perturbation theory that truncates at some finite order so that all results are exact. We illustrate the general theory at the example of dimensional theories with supersymmetry for which we recover known superblocks. The paper concludes with an outlook to 4-dimensional blocks with supersymmetry.
Cite
@article{arxiv.1904.04852,
title = {Superconformal Blocks: General Theory},
author = {Ilija Buric and Volker Schomerus and Evgeny Sobko},
journal= {arXiv preprint arXiv:1904.04852},
year = {2020}
}
Comments
JHEP format, an appendix and remarks added, typos corrected