What question did this study set out to answer?

This addendum aims to demonstrate that Mercury's perihelion precession can be derived using fluid dynamics principles within a Quantum-Crystalline medium.

June 3, 2026Open Access

Mathematical Addendum to ARTICLE NO. 8: Viscous Derivation of Mercury's Perihelion Precession

Key Points

This addendum aims to demonstrate that Mercury's perihelion precession can be derived using fluid dynamics principles within a Quantum-Crystalline medium.
Rigorous mathematical derivation of Mercury's perihelion precession.
Integration of the Zolottcev Viscous Stress Tensor into the effective orbital potential.
Analysis of viscous dynamics as Mercury approaches the Sun.
The exact precession value of 43 arcseconds per century is replicated using fluid dynamics.
Localized viscous saturation causes a hydrodynamic delay at the orbital turning point.
Demonstrates unification of gravitational mechanics through the framework of hydrodynamics.

Abstract

This addendum provides a rigorous mathematical derivation of Mercury's perihelion precession within the framework of the Quantum-Crystalline (QC) medium. Standard astrophysics attributes the 43 arcseconds per century orbital shift to the geometric curvature of empty spacetime as described by General Relativity. Here, it is demonstrated that this exact precession value emerges deterministically from fluid dynamics. As Mercury approaches the Sun (perihelion), it encounters an exponential gradient of dynamic vacuum viscosity. This localized viscous saturation induces a hydrodynamic delay at the orbital turning point. By integrating the Zolottcev Viscous Stress Tensor into the effective orbital potential, the classical relativistic shift is fully replicated via the physical friction of the QC-medium, further solidifying the unification of gravitational mechanics under hydrodynamics.

Mathematical Addendum to ARTICLE NO. 8: Viscous Derivation of Mercury's Perihelion Precession

Key Points

Abstract

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