MSSM Based Theory for Planck Precision Results (2018), Dark Matter, Dark Energy and Solution of Cosmological Problems

TL;DR

This paper presents a MSSM-based theoretical framework that reproduces Planck satellite measurements of cosmological parameters and predicts particle masses consistent with experiments, addressing key cosmological and particle physics problems.

Contribution

It introduces a novel MSSM approach that links gauge boson masses to cosmological data and predicts new particle masses, bridging cosmology and particle physics.

Findings

Reproduces Planck cosmological parameters using MSSM calculations.

Predicts nucleon and Higgs boson masses aligning with experimental data.

Suggests future collider experiments can verify predicted particle masses.

Abstract

We demonstrate that precision measurements of cosmological parameters from the Planck Satellite Observatory (2018) can be accurately reproduced by calculating the masses of gauge bosons and their superpartners within the Minimal Supersymmetric Standard Model (MSSM). Our approach utilizes combined decay product equations from these gauge supermultiplets. These results strongly support the Lambda-CDM cosmological standard model. Moreover, our equations predict the masses of the ordinary nucleon, a proposed anti-supersymmetric nucleon (as a dark matter candidate), and the Higgs boson in agreement with experimental values. Our theory addresses baryon number violation, lepton number violation, and the matter-antimatter asymmetry of the universe. We anticipate that the masses of winos and anti-supersymmetric nucleons will be verified through Higgs boson decay in top-anti-top quark interactions at future high-energy hadron collider experiments.