English

Conformal interactions between matter and higher-spin (super)fields

High Energy Physics - Theory 2023-01-25 v3

Abstract

In even spacetime dimensions, the interacting bosonic conformal higher-spin (CHS) theory can be realised as an induced action. The main ingredient in this definition is the model S[φ,h]\mathcal{S}[\varphi,h] describing a complex scalar field φ\varphi coupled to an infinite set of background CHS fields hh, with S[φ,h]\mathcal{S}[\varphi,h] possessing a non-abelian gauge symmetry. Two characteristic features of the perturbative constructions of S[φ,h]\mathcal{S}[\varphi , h] given in the literature are: (i) the background spacetime is flat; and (ii) conformal invariance is not manifest. In the present paper we provide a new derivation of this action in four dimensions such that (i) S[φ,h]\mathcal{S}[\varphi , h] is defined on an arbitrary conformally-flat background; and (ii) the background conformal symmetry is manifestly realised. Next, our results are extended to the N=1\mathcal{N}=1 supersymmetric case. Specifically, we construct, for the first time, a model S[Φ,H]\mathcal{S}[\Phi, H] for a conformal scalar/chiral multiplet Φ\Phi coupled to an infinite set of background higher-spin superfields HH. Our action possesses a non-abelian gauge symmetry which naturally generalises the linearised gauge transformations of conformal half-integer superspin multiplets. The other fundamental features of this model are: (i) S[Φ,H]\mathcal{S}[\Phi, H] is defined on an arbitrary conformally-flat superspace background; and (ii) the background N=1\mathcal{N}=1 superconformal symmetry is manifest. Making use of S[Φ,H]\mathcal{S}[\Phi, H], an interacting superconformal higher-spin theory can be defined as an induced action.

Keywords

Cite

@article{arxiv.2208.07783,
  title  = {Conformal interactions between matter and higher-spin (super)fields},
  author = {Sergei M. Kuzenko and Michael Ponds and Emmanouil S. N. Raptakis},
  journal= {arXiv preprint arXiv:2208.07783},
  year   = {2023}
}

Comments

69 pages; V2: References and new comments added, typos corrected; V3: Published version

R2 v1 2026-06-25T01:44:34.150Z