What question did this study set out to answer?

This work aims to establish a unified 5D framework to enhance understanding of singularities and vacuum properties.

April 27, 2026Open Access

The Minkowski-Kaluza-Klein-Măgureanu (MKKM) R5 Framework: Mechanical Rigidity and Singularity Suppression.

Key Points

This work aims to establish a unified 5D framework to enhance understanding of singularities and vacuum properties.
Developed the MKKM model based on wave-mechanical traditions.
Derived geometric surface tension and topological angular capacity from the model.
Discussed implications in experimental settings like high-current relativistic beams.
Established vacuum impedance geometrically.
Demonstrated the elimination of 0D singularities via a 'Geometric Floor'.
Resolved the Information Paradox by outlining formation of stable remnants.

Abstract

This work presents the Minkowski-Kaluza-Klein-Măgureanu (MKKM) model, a 5D unified framework that replaces the traditional compactification of Kaluza-Klein theory with a macroscopic spatial extension. Rooted in the wave-mechanical tradition of Louis de Broglie and developed during doctoral research under Prof. Marius Borneas (West University of Timișoara), this framework treats the vacuum as a high-tension physical manifold. We derive a geometric surface tension of N/m and a topological angular capacity of steradians. The model provides a mechanical derivation for the vacuum impedance and establishes a 'Geometric Floor' that eliminates 0D singularities, resolving the Information Paradox through the formation of stable remnants. Experimental implications for high-current relativistic beams, such as those utilized at the TRIUMF 500 MeV cyclotron, are also discussed

The Minkowski-Kaluza-Klein-Măgureanu (MKKM) R5 Framework: Mechanical Rigidity and Singularity Suppression.

Key Points

Abstract

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