20 Observable Predictions of Quarkbase Cosmology

This work presents the first unified catalogue of twenty fully testable and falsifiable predictions derived from Quarkbase Cosmology, a pressure-field framework in which comet activation, graphene transport, galactic structure, quantum coherence, and nuclear energetics emerge from the same scalar field Ψ.

Each prediction is formulated with explicit observables and strict falsifiability criteria. The cometary predictions identify universal activation bands, diagonal correlations in the (r_onset, Q_CO2/Q_H2O) plane, tension curves in production rates, jet–polarization alignment, and the reconstruction of a 3D galactic pressure map.

In condensed matter, the theory predicts the exact graphene absorbance (π α_QB ≈ 2.30%), superconductivity without Cooper pairs, Ψ-mediated thermal hyperconductivity, and Tc tunability via geometric deformation.

On cosmological scales, it predicts Yukawa-based rotation curves (λ ≈ 50 kpc), filamentary large-scale structure as Ψ-interference, redshift evolution governed by n(t) rather than metric expansion, and a fixed supercluster scale.

At the quantum level, double-slit impacts must show Ψ self-focusing, and entanglement must persist as a continuous extended mode. In nuclear physics, the 200 MeV fission energy of 235U must be reproduced purely from Ψ-pressure geometry, without invoking mass defects.

Any single contradictory observation falsifies the framework. Conversely, coherent confirmation across these domains would support Quarkbase Cosmology as a unified replacement for multiple disconnected physical models.