On phase-space singular surfaces in f(R) gravity

Abstract

We perform a Hamiltonian constraint analysis of metric f(R) gravity in the Jordan frame and show that the regular constraint classification degenerates on singular phase-space surfaces located at f'(R)\!=\!0 and f''(R)\!=\!0. We then study the perturbative implications of these surfaces. For exact backgrounds satisfying f(R)\!=\!0 and f'(R)\!=\!0, the linearized spectrum is empty; the known pure R2 result is therefore a special case of a more general degeneracy in f(R) gravity. We also show that FLRW trajectories in the Starobinsky model can cross the surface f'(R)=0, but that inhomogeneous perturbations develop a degenerate constraint structure at the crossing. The resulting crossing condition is better interpreted as a regularity condition for perturbative evolution than as an ordinary constraint within the Dirac--Bergmann algorithm. Together, these results distinguish backgrounds that lie entirely on a singular surface from backgrounds that cross one dynamically, and show that the two situations lead to different perturbative degeneracies.