The Secrets of Black Holes and the Higgs Mass Could Be Hidden in a 7-Dimensional Geometry

The black‑hole information paradox has haunted physicists since Hawking showed that evaporating black holes seemingly erase quantum data. Traditional approaches either modify quantum mechanics or invoke exotic firewalls, but the new Einstein‑Cartan framework adds a twist—literally—by allowing spacetime to possess torsion. In a seven‑dimensional G₂‑manifold, this torsion becomes repulsive at Planck‑scale densities, arresting the final stages of evaporation and producing a Planck‑mass relic. This geometric fix sidesteps the need for radical quantum revisions while staying within a well‑defined extension of general relativity.

Beyond stopping evaporation, the remnant acts as a cosmic hard drive. Its quasi‑normal mode spectrum can store an astronomical number of qubits, matching the information content of a solar‑mass black hole. The same torsion field that stabilizes the relic acquires a vacuum expectation value that, after compactifying the extra dimensions, aligns with the electroweak scale of 246 GeV. This provides a fresh, purely geometric explanation for the Higgs mass and the long‑standing hierarchy problem, linking the microphysics of particle masses to the macroscopic behavior of black holes.

Testing the proposal does not require a 10¹⁶ GeV collider. The predicted remnants, with masses near 9×10⁻⁴¹ kg, could contribute to dark matter and leave subtle gravitational imprints detectable by next‑generation microlensing surveys or pulsar timing arrays. Additionally, the early‑universe dynamics of the 7‑dimensional geometry may have imprinted signatures in the cosmic microwave background or primordial gravitational‑wave background. If such clues emerge, they would not only validate a bold unification of gravity and particle physics but also open a new observational window onto extra dimensions.