English

Frobenius-Chern-Simons gauge theory

High Energy Physics - Theory 2017-02-01 v1

Abstract

Given a set of differential forms on an odd-dimensional noncommutative manifold valued in an internal associative algebra H, we show that the most general cubic covariant Hamiltonian action, without mass terms, is controlled by an Z_2-graded associative algebra F with a graded symmetric nondegenerate bilinear form. The resulting class of models provide a natural generalization of the Frobenius-Chern-Simons model (FCS) that was proposed in arXiv:1505.04957 as an off-shell formulation of the minimal bosonic four-dimensional higher spin gravity theory. If F is unital and the Z_2-grading is induced from a Klein operator that is outer to a proper Frobenius subalgebra, then the action can be written on a form akin to topological open string field theory in terms of a superconnection valued in the direct product of H and F. We give a new model of this type based on a twisting of C[Z_2 x Z_4], which leads to self-dual complexified gauge fields on AdS_4. If F is 3-graded, the FCS model can be truncated consistently as to zero-form constraints on-shell. Two examples thereof are a twisting of C[(Z_2)^3] that yields the original model, and the Clifford algebra Cl_2n which provides an FCS formulation of the bosonic Konstein--Vasiliev model with gauge algebra hu(4^{n-1},0).

Keywords

Cite

@article{arxiv.1607.00726,
  title  = {Frobenius-Chern-Simons gauge theory},
  author = {Roberto Bonezzi and Nicolas Boulanger and Ergin Sezgin and Per Sundell},
  journal= {arXiv preprint arXiv:1607.00726},
  year   = {2017}
}

Comments

44 pages

R2 v1 2026-06-22T14:42:07.486Z