Axions on a Hyperbolic Ride: Geometric Suppression of CMB Isocurvature and a Blue-Tilted Spectrum

Abstract

CMB limits on cold-dark-matter isocurvature are often interpreted as excluding the simultaneous realization of high-scale inflation and large QCD axion decay constants in pre-inflationary Peccei--Quinn (PQ) scenarios. This conclusion can be evaded by exploiting field-space geometry. For a minimal complex PQ scalar with a U(1)-symmetric potential and a nonlinear sigma-model kinetic term dσ2=dR2+f2(R)\,dθ2, the observable axion fluctuation is δθ H inf/f(R), so an enhanced effective decay constant f(R) suppresses isocurvature without explicit PQ breaking, extreme radial displacements, or additional couplings. We specialize to a hyperbolic metric f(R) (R/L) with curvature scale L. The same geometry also induces a time-dependent O(H inf) effective mass for the canonical axial mode during radial slow-roll, and fixing the tilt and running of isocurvature. Thus, CMB-scale isocurvature is suppressed while a characteristic blue-tilted spectrum is generated. As a result, inflationary Hubble scales as large as H inf 1013\,GeV can be compatible with fa 1014--1016\,GeV, reopening parameter space usually regarded as excluded. We present `observable' benchmarks and a semi-analytic template that relates the scale-dependence of isocurvature to the geometric lever arm R/L, providing a direct phenomenological probe on PQ field-space geometry.