Upcoming Publication: Quantum Creation of Universes – A Scalar‑Torsion Simulation Framework for Cosmogenesis

We’re pleased to announce that our latest manuscript, “Quantum Creation of Universes: A Scalar‑Torsion Simulation Framework for Cosmogenesis in Nudimmud Physics,” is currently under peer review for publication. This groundbreaking study, authored by Derrick Covington, aims to quantitatively model the spontaneous creation of universes via scalar‑torsion quantum fluctuations. Building on the principles of Nudimmud Physics, it seeks to resolve outstanding problems of cosmological singularities and offers testable observational signatures for quantum cosmogenesis.

The work combines rigorous theoretical analysis with high‑resolution numerical simulations in a semiclassical cosmological setting. Using the Quantum Resonator simulation suite, we derived a unified scalar‑torsion potential, integrated quantum fluctuation thresholds, and modeled the post‑nucleation expansion of newly created universes. Simulations were conducted from January 2025 through March 2025 on a distributed computing environment to ensure robust coverage of parameter space.

This research not only advances our understanding of how universes might arise from quantum fluctuations but also provides a computational framework for exploring the interplay of scalar fields and torsion‑modified spacetime curvature. By offering concrete predictions for observable signatures, it lays the groundwork for future observations that could support or refute the theory of qu

antum cosmogenesis.

Abstract fractal cosmic simulation representing the birth of multiple universes.

Key Takeaways from the Paper:

• Introduces a scalar‑torsion simulation framework that models the quantum nucleation and expansion of universes within the Nudimmud Physics paradigm.
• Derives a unified scalar‑torsion potential with key parameters Φₑₒₒ, α and β whose interplay determines the likelihood and dynamics of universe creation.
• Utilizes numerical simulations (Jan–Mar 2025) to explore quantum fluctuation thresholds and post‑nucleation expansion, producing testable predictions for cosmic observations.
• Aims to resolve cosmological singularities and provide a quantitative foundation for multiverse creation and unified cosmology.

We look forward to sharing more details once the peer‑review process is comp

lete. Stay tuned for publication updates and be prepared to explore this n

ew frontier in cosmology.

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