Abstract

In a multi-fold universe, gravity emerges from Entanglement through the multi-fold mechanisms. As a result, gravity-like effects appear in between entangled particles that they be real or virtual. Long range, massless gravity results from entanglement of massless virtual particles. Entanglement of massive virtual particles leads to massive gravity contributions at very smalls scales. Multi-folds mechanisms also result into a spacetime that is discrete, with a random walk fractal structure, and non-commutative geometry that is Lorentz invariant and where spacetime nodes and particles can be modeled with microscopic black holes. All these recover General relativity at large scales, and semi-classical model remain valid till smaller scale than usually expected. Gravity can therefore be added to the Standard Model (SM) resulting into what we defined as SMG. This can contribute to resolving several open issues with the Standard Model without new Physics other than gravity. These considerations hint at an even stronger relationship between gravity and the Standard Model.This paper investigates the details of modeling particles as microscopic black holes previously proposed during multi-fold spacetime reconstruction. We reuse work done on Kerr Newman regularization, by modeling the region inside the singularity ring as a Dirac soliton in Kerr-Newman metric within a kind of Q-ball where the Higgs field condense, due to its symmetry being broken. The Q-ball edge appears superconductive with an oblateness that for the electron is given by the fine structure constant. It recovers charged particle scatterings, spin quantization, magnetic momentum. Massless particles and concretized spacetime are modeled by Schwarzschild black holes. Our analysis is the result of combining different results obtained by others, but re-interpreted when put together in the context of multi-fold mechanisms. The analysis also clarifies and reinforces our proposals for the role of Higgs boson, the Higgs field and the Ultimate Unification (UU) in multifold universes, in term of random walk, spacetime point concretization, and inflation. We also confirm the possible relationship between supersymmetry, superstrings, 2D gravity and multi-fold random walks in multifold spacetime reconstructions. Indeed the formers can approximate the random walks, something we already concluded in recent papers. At large scale, all these models seem to converge even if the challenges related to asymptotic safety and SM remain a problem for superstrings and supersymmetry.