The Ambient Space Formalism
Abstract
We present a new formalism to solve the kinematical constraints due to Weyl invariance for CFTs in curved backgrounds and/or non-trivial states, and we apply it to thermal CFTs and to CFTs on squashed spheres. The ambient space formalism is based on constructing a class of geometric objects that are Weyl covariant and identifying them as natural building blocks of correlation functions. We construct (scalar) -point functions and we illustrate the formalism with a detailed computation of 2-point functions. We compare our results for thermal 2-point functions with results that follow from thermal OPEs and holographic computations, finding exact agreement. In our holographic computation we also obtain the OPE coefficient of the leading double-twist contribution, and we discuss how the double-twist coefficients may be computed from the multi-energy-momentum contributions, given knowledge of the analytic structure of the correlator. The 2-point function for the CFT on squashed spheres is a new result. We also discuss the relation of our work to flat holography.
Cite
@article{arxiv.2312.03820,
title = {The Ambient Space Formalism},
author = {Enrico Parisini and Kostas Skenderis and Benjamin Withers},
journal= {arXiv preprint arXiv:2312.03820},
year = {2024}
}
Comments
93 pages, 6 figures; v2: improvements and references added; v3: published version