Emergent spacetime from spatial energy potentiality: a new theoretical framework for early universe cosmology
Abstract
We develop a comprehensive cosmological framework based on the principle that our universe originated as a three-dimensional spatial configuration governed purely by energy functionals, with time emerging dynamically through quantum loop corrections. Building on the Unified Standard Model with Emergent Gravity-Effective Field Theory (USMEG-EFT), which provides the first successful unification of quantum gravity with the Standard Model, we demonstrate that spacetime emergence occurs via a first-order phase transition when quantum-generated kinetic terms exceed a critical threshold. This transition naturally resolves the cosmological singularity problem: all curvature invariants remain finite, with R/MP4 10-44 and K/MP8 10-88 at the critical point. The framework makes definitive, parameter-free predictions for gravitational wave polarizations, exactly two tensor modes confirmed by LIGO-Virgo-KAGRA observations at >99\% confidence, excluding competing approaches that predict additional scalar, vector, or modified polarization content. Post-emergence dynamics naturally implements Starobinsky inflation with spectral index ns = 0.964 and tensor-to-scalar ratio r = 0.004, in excellent agreement with Planck constraints. The phase transition dynamics generate enhanced primordial non-Gaussianity f NL local ∈ [0.8, 2.5], testable with CMB-S4 (projected σ 1), and a stochastic gravitational wave background peaking in the LISA sensitivity band (f 10-4 Hz, GWh2 10-6). The framework naturally addresses the Hubble tension through scale-dependent modifications to cosmic expansion arising from residual phase transition effects.
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