Worldline Higher Spin Gravity
Abstract
We propose a worldline formulation of higher-spin gravity (HSG) in , based on a simple twistor action. Taken at face value, the model describes only the free propagation of massless higher-spin fields. The central observation of this work is that the model admits a natural double-line interpretation, which supplies a geometric prescription for gluing worldlines at interaction vertices, in close parallel with the joining of strings in string theory. Building on this picture, we construct -covariant vertex operators for all massless higher-spin fields, show that they satisfy the Bargmann-Wigner equations, and use them to compute the n-point correlation functions of type-A and type-B HSG as worldline path integrals of these vertex operators. In the boundary limit these correlators reproduce the higher-spin current correlators of free boson and free fermion vector models. We further discuss the embedding of the worldline theory into Poisson sigma model, where the doubled-line structure acquires a geometric origin as the two edges of an open string worldsheet, together with several consequences of this enlarged framework -- fractional branes, loop expansion, unoriented projection, and the prospect of a worldsheet formulation of HSG.
Cite
@article{arxiv.2605.27956,
title = {Worldline Higher Spin Gravity},
author = {Minkyeu Cho and Euihun Joung and Taehwan Oh and Tung Tran},
journal= {arXiv preprint arXiv:2605.27956},
year = {2026}
}
Comments
46 pages