Robust Non-Singular Bouncing Cosmology from Regularized Hyperbolic Field Space
Abstract
We present a framework for non-singular bouncing cosmology in a closed (k=+1) universe with a two-field sigma model whose regularized hyperbolic field-space metric gS(φ) = (1 + e-2αφ/MPl)-1 is derived from three physical boundary conditions: (i) kinetic suppression during contraction enabling the bounce, (ii) canonical normalization during inflation preserving perturbative unitarity, and (iii) positive-definiteness ensuring ghost-freedom. The bounce preserves the Null Energy Condition and is BKL-stable. The full two-field perturbation system (δφ, δ, ) is integrated in the Newtonian gauge through the bounce over 65 e-folds, circumventing the comoving-gauge H=0 singularity, with both Einstein constraints verified a posteriori. Scalar sound speeds numerically measured adjacent to H=0 satisfy |cφ2-1|, |c2-1| ≤ 8 × 10-16, establishing strict hyperbolicity (no ghost or gradient instability); R is conserved on super-Hubble scales to |2/R2| = 4.43 × 10-3. An independent CMB-scale Mukhanov-Sasaki integration confirms ns = 0.9683, matching exact Starobinsky slow-roll to | ns| = 5.47 × 10-4. δ N non-Gaussianity yields fNLlocal = +0.0133, consistent with Maldacena's relation to | fNL| = 1.54 × 10-4. A bounce-scale spectral feature is pushed by 2630 post-bounce e-folds to kCMB/kH 101116, far beyond the observable universe, so the model recovers Starobinsky predictions on all observable scales while resolving the initial singularity. Predictions (ns ≈ 0.967, r ≈ 0.003, fNLlocal ≈ +0.013, independent of α) are consistent with Planck 2018 and testable by next-generation CMB experiments.
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