Journal of Scientific Research and Reports

Aims: To develop a unified scalar-torsion cosmological framework—Nudimmud Physics—that resolves quantum gravity and cosmological singularities, and to validate its predictive capability through explicit comparison with established cosmological models and observational data.

Study Design: Theoretical and computational comparative study at GreenTheDream.com

Place and Duration of Study: Department of Theoretical Physics and Computational Cosmology at GreenTheDream.com, conducted from March 2024 to March 2025.

Methodology: We constructed a simplified unified scalar potential derived from scalar-torsion cosmology, quantum gravity principles inspired by Loop Quantum Gravity, and scalar moduli stabilization mechanisms from String Theory. Numerical simulations were conducted to explore cosmological dynamics across bounce scenarios, focusing on scalar potential behaviors, cosmological growth factors, and observable parameters such as matter clustering and Hubble expansion rates.

Results: Simulations using the refined unified scalar potential demonstrated smooth cosmological bounce behavior, effectively resolving the cosmological singularity at a cosmic scale factor of zero. Predictive results indicated enhanced matter clustering with a clustering amplitude  and an increased Hubble constant of  compared to standard cosmological observations (DESI data). The unified framework showed excellent alignment with both Loop Quantum Gravity and String Theory scalar moduli stabilization

Nudimmud Physics successfully resolves fundamental cosmological and quantum gravity issues through a simplified, testable unified scalar-torsion model. It provides robust predictions that can be validated by contemporary cosmological surveys, potentially advancing our understanding of universe dynamics and offering a simplified alternative for scalar field stabilization in theoretical cosmology.

Scalar-Torsion Dynamics and Nudimmud Physics: At the heart of Nudimmud Physics lies a scalar field coupled not only to the curvature of spacetime, but also to its intrinsic torsion a geometric twist encoded in the antisymmetric component of the affine connection. This scalar-torsion coupling produces nonlinear feedback loops in the evolution of the universe, stabilizing the quantum vacuum and allowing for smooth bounce solutions where singularities would otherwise form. The theory unifies moduli stabilization, bounce cosmology, and quantum gravity under a single analytic framework that is both mathematically elegant and computationally testable. Torsion acts as a memory field, encoding the prior curvature history and facilitating energy redistribution during quantum transitions, while the scalar field governs large-scale coherence and structure formation. This dynamic interplay gives rise to fractal-like branching universes, recursive field tearing, and potential mechanisms for cosmological self-replication. Nudimmud Physics thus presents a powerful foundation for simulating early-universe conditions, field-induced creation events, and the emergence of multiverse structures bridging the gap between macroscopic geometry and quantum informational flux.