Models for (super)conformal higher-spin fields on curved backgrounds
Abstract
This thesis is devoted to the construction of theories describing the consistent propagation of (super)conformal higher-spin fields on curved three- and four-dimensional (super)spaces. In the first half of this thesis we systematically derive models for conformal fields of arbitrary rank on various types of curved spacetimes. On generic conformally-flat backgrounds in three and four dimensions, we obtain closed-form expressions for the actions which are manifestly gauge and Weyl invariant. Similar results are provided for generalised conformal fields, which have higher-depth gauge transformations. In three dimensions, conformally-flat spacetimes are the most general backgrounds allowing consistent propagation. In four dimensions, it is widely expected that gauge invariance can be extended to Bach-flat backgrounds, although no complete models for spin greater than two exist. We confirm these expectations for the first time by constructing a number of complete gauge-invariant models for conformal fields with higher spin. In the second half of this thesis we employ superspace techniques to extend the above results to conformal higher-spin theories possessing off-shell supersymmetry. Several novel applications of our results are also provided. In particular, transverse projection operators are constructed in anti-de Sitter (AdS) space, and their poles are shown to be associated with partially-massless fields. This allows us to demonstrate that on such backgrounds, the (super)conformal higher-spin kinetic operator factorises into products of second order operators. Similar conclusions are drawn in AdS (super)space. Finally, we make use of the (super)conformal higher-spin models in Minkowski and AdS (super)space to build topologically massive gauge theories.
Cite
@article{arxiv.2201.10163,
title = {Models for (super)conformal higher-spin fields on curved backgrounds},
author = {Michael Ponds},
journal= {arXiv preprint arXiv:2201.10163},
year = {2022}
}
Comments
PhD thesis, 302 pages. Based on arXiv:1806.06643, arXiv:1812.05331, arXiv:1902.08010, arXiv:1910.10440, arXiv:1912.00652, arXiv:2005.08657, arXiv:2011.11300, 2101.05524, arXiv:2103.11673 and arXiv:2107.12201