​​​​​​Ariel Fernandez​

Scientist - Consultant

Chirality-Flipping Boson: Architect of the Dark Sector and the Hierarchy Scale

Ariel Fernández Stigliano

ORCID: https://orcid.org/0000-0002-5102-4294
 

   My research focuses on topological field theory of the dark sector. Specifically, it focuses on the identification and characterization of an ultra-light (10^-14 eV) chirality-flipping scalar field, the phi-boson, as the transition operator of non-orientable spacetime. By replacing the t=0 singularity with a finite, chiral-flipping "twist" between twin sheets, this topology avoids the big bang infinite density via a geometric bypass.

   Rather than an empirical fit to cosmological data, the observed 5:1 ratio of dark-to-visible matter will be derived as a rigorous algebraic topology result. By computing the topological organization of a non-orientable spacetime, we shall demonstrate that the simplest stable state for such a manifold occurs at winding number Q=6. Within this six-fold architecture, global time-foliation is mathematically restricted to a single 'visible' tier, while the remaining five 'twisted' sheets constitute the dark sector. This identifies the dark-to-visible abundance as a topological ground state, providing a first-principles explanation for both the universe’s mass density and the 0.35° cosmic birefringence observed in Planck satellite data.

   Using the ECSK framework, we intend to prove that the non-orientable seams trap Majorana fermion condensates geometrically locked to the phi-field via a BPS stability condition and scaled by the electroweak vacuum (eta=246GeV).  Crucially, we resolve the Hierarchy Problem by identifying gravity as the topological dilution of the electroweak torsional tension. The Q=6 configuration generates a combinatorial topological entropy that scales the 246 GeV "twist" down to the Newtonian constant, rendering the Planck scale an emergent projection of the electroweak manifold.

  This research shifts the dark matter paradigm from particle discovery to topological derivation, offering a concrete target for nuclear clocks to detect the phi-field’s 3 Hz Compton "hum."

Reference: Ariel Fernandez Stigliano (2026) Artificial Conscience for the Quantum Physicist. CRC Press, Routledge, Taylor & Francis.