The cosmological collider in $R^2$ inflation

Starobinsky's $R^2$ inflation manifests a best-fit scenario for the power spectrum of primordial density fluctuations. Observables derived from the slow-roll picture of the $R^2$ model in the Einstein frame relies on the conformal transformation of the metric, which inevitably induces a unique exponential-type couplings of the rolling scalaron with all matter fields during inflation. The "large-field" nature of the $R^2$ model further invokes non-negligible time and scale dependence to the matter sector through such an exponential coupling, modifying not only the dynamics of matter perturbations on superhorizon scales but also their decay rates. In this work, we identify the simplest observable of the cosmological collider physics built in the background of $R^2$ inflation, focusing on the so-called "quantum primordial clock" signals created by the non-local propagation of massive scalar perturbations. Our numerical formalism based on the unique conformal coupling can have extended applications to (quasi-)single-field inflationary models with non-trivial couplings to gravity or models originated from the $f(R)$ modification of gravity.
Comment: 34 + 3 pages, 8 figures; added conditions for tree-level exchanges with an appendix for models in the mixed Higgs-$R^2$ inflation; references added; version matched with publication