English

Edge modes as reference frames and boundary actions from post-selection

High Energy Physics - Theory 2022-02-24 v4 General Relativity and Quantum Cosmology Quantum Physics

Abstract

We introduce a general framework realizing edge modes in (classical) gauge field theory as dynamical reference frames, an often suggested interpretation that we make entirely explicit. We focus on a bounded region MM with a co-dimension one time-like boundary Γ\Gamma, which we embed in a global spacetime. Taking as input a variational principle at the global level, we develop a systematic formalism inducing consistent variational principles (and in particular, boundary actions) for the subregion MM. This relies on a post-selection procedure on Γ\Gamma, which isolates the subsector of the global theory compatible with a general choice of gauge-invariant boundary conditions for the dynamics in MM. Crucially, the latter relate the configuration fields on Γ\Gamma to a dynamical frame field carrying information about the spacetime complement of MM; as such, they may be equivalently interpreted as frame-dressed or relational observables. Generically, the external frame field keeps an imprint on the ensuing dynamics for subregion MM, where it materializes itself as a local field on the time-like boundary Γ\Gamma; in other words, an edge mode. We identify boundary symmetries as frame reorientations and show that they divide into three types, depending on the boundary conditions, that affect the physical status of the edge modes. Our construction relies on the covariant phase space formalism, and is in principle applicable to any gauge (field) theory. We illustrate it on three standard examples: Maxwell, Abelian Chern-Simons and non-Abelian Yang-Mills theories. In complement, we also analyze a mechanical toy-model to connect our work with recent efforts on (quantum) reference frames.

Keywords

Cite

@article{arxiv.2109.06184,
  title  = {Edge modes as reference frames and boundary actions from post-selection},
  author = {Sylvain Carrozza and Philipp A. Hoehn},
  journal= {arXiv preprint arXiv:2109.06184},
  year   = {2022}
}

Comments

76 pages, comments welcome; v4: journal version, accepted in JHEP

R2 v1 2026-06-24T05:55:47.560Z