From the Cosmological Constant: Higgs Boson, Dark Matter, and Quantum Gravity Scales

TL;DR

This paper proposes a theoretical framework linking the Higgs boson, dark matter, and quantum gravity scales through constraints derived from the Dirac equation in deSitter space, suggesting new discovery targets and cosmic horizons.

Contribution

It introduces a novel sixth-order constraint connecting electron QED parameters with the cosmological constant, leading to predictions of mass scales and a new cosmic horizon.

Findings

Derived electron neutrino mass from dual constraints

Proposed new cosmic horizon based on theoretical constraints

Identified potential discovery targets for fundamental particles

Abstract

We suggest discovery targets for the Higgs boson, dark matter, and quantum gravity mass scales, motivated by the Dirac equation for the electron in deSitter space, and a sixth-order constraint between the electron QED parameters and the cosmological constant. We go on to show that this constraint can be viewed as a structural parameter of the electron, and leads naturally to a new cosmic horizon. A dual fourth-order constraint implies a second-order one, from which the electron neutrino mass is derived.