Precision Cryptographic Calculation of the Observed Values of the Cosmological Constants {\Omega}{\Lambda} and {\Omega}m as a Manifestation of the Higgs State in the Extension Field

TL;DR

This paper presents a cryptographic approach linking the Higgs field to cosmological constants, achieving precise theoretical values that match observed data and suggesting a deep connection between micro-scale physics and cosmic-scale parameters.

Contribution

It introduces a novel cryptographic framework connecting the Higgs state to cosmological constants, providing exact theoretical values aligned with observations.

Findings

Theoretical values of cosmological constants match observed ranges.

A cryptographic method links micro-scale couplings to cosmic parameters.

The approach confirms the flatness condition of the universe.

Abstract

The Higgs concept can be assigned a precise quantitative cosmic identity with a physically anchored cryptographic analysis. Specifically demonstrated is the direct correspondence of the supersymmetric solution pair (BHh1 and BHh2) of the Higgs Congruence in the extension field to the observed magnitudes of the cosmological constants and . These results are in perfect agreement with the maximally preferred magnitudes of these quantities as experimentally determined (0.712 < {\Omega}{\Lambda}< 0.758 and 0.242 < {\Omega}m< 0.308) by the concordance of measured ranges. The corresponding theoretical values found also satisfy exactly the condition for perfect flatness, an outcome that is legislated by the concept of supersymmetry in . Since previous work has established that the fine-structure constant {\alpha} can be uniquely computed in the corresponding physically defined prime field, in sharp accord with the best high-precision measurement (~370 ppt) of {\alpha}, the computation of and with the identical cryptographic apparatus demonstrates that a precise quantitative relationship exists between fundamental micro-scale couplings and the largest cosmic-scale entities. Since both fields and are fully defined by the prime (mod 4), the alliance of these quantitative findings relating provides additional confirming evidence for the correctness of its previously established physically based magnitude. Ultimately, a coherent synthesis is achieved in conformance with observational data that quantitatively relates the six physically intrinsic universal parameters {\alpha}, G, h, c, {\Omega}{\Lambda}, and {\Omega}m.