What question did this study set out to answer?

The research aims to explain the formation of charged-lepton mass hierarchy using redistribution dynamics in the ψ₀–OCM model.

May 18, 2026Open Access

Charged-Lepton Mass Closure from Boundary-Stabilized Redistribution in ψ₀-OCM

Key Points

The research aims to explain the formation of charged-lepton mass hierarchy using redistribution dynamics in the ψ₀–OCM model.
Developed a redistribution-first derivation approach for charged-lepton mass hierarchy.
Explored boundary-stabilized configurations and their topology-constrained stabilization eigenvalues.
Provided falsification criteria for the proposed model and collider-scale tests.
Reproduced known mass hierarchies of electron, muon, and tau from boundary-stabilized dynamics.
Demonstrated compatibility with effective Standard Model phenomenology under stabilization-locked conditions.
Proposed collider-scale discriminators for testing the model's predictions.

Abstract

This paper develops a redistribution-first derivation of charged-lepton mass hierarchy formation within the ψ₀–OCM (Osborne Cosmological Model). Charged leptons are modeled as stabilized boundary-closure configurations emerging from admissible redistribution dynamics rather than as fundamental point particles with arbitrary Yukawa assignments. The framework derives charged-lepton mass scaling through topology-constrained stabilization eigenvalues, boundary invariants, and redistribution closure conditions. Known electron, muon, and tau mass hierarchy structure is recovered through boundary-stabilized redistribution relations while preserving compatibility with effective Standard Model phenomenology in stabilization-locked regimes. The paper provides explicit falsification criteria and proposes collider-scale residual discriminators associated with redistribution substructure.

Charged-Lepton Mass Closure from Boundary-Stabilized Redistribution in ψ₀-OCM

Key Points

Abstract

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