Pinčák Proposes 7-Dimensional Black Hole Remnants Preserve 1.5×10^77 Qubits
Updated
Updated · ScienceDaily · Jul 5
Pinčák Proposes 7-Dimensional Black Hole Remnants Preserve 1.5×10^77 Qubits
2 articles · Updated · ScienceDaily · Jul 5
Summary
A new theoretical study argues black holes do not fully evaporate but stop at the last stage, leaving stable remnants that retain the information swallowed during collapse.
In Richard Pinčák's model, torsion in a 7-dimensional Einstein-Cartan framework creates a repulsive effect at Planck-scale densities, halting Hawking evaporation and producing a remnant of about 9×10^-41 kg.
That remnant could store roughly 1.515×10^77 qubits for a solar-mass black hole, with information encoded in long-lived quasi-normal-mode vibrations of the torsion field.
The same geometry also yields the electroweak scale near 246 GeV, linking the black hole proposal to a possible explanation for how elementary particles acquire mass.
Direct collider tests look out of reach because related excitations sit near 8.6×10^15 GeV, but the authors say dark-matter signatures, primordial gravitational waves and cosmic microwave background traces could still probe the idea.
Could the universe's dark matter be tiny, information-filled remnants left over from evaporated black holes?
Does the mass of every particle truly originate from the geometry of unseen, higher dimensions?
Black Hole Information Paradox Resolved? The Case for Stable Remnants and Hidden Dimensions in Modern Physics
Overview
In April 2026, Richard Pinčák and his team proposed a breakthrough idea: black holes may not fully evaporate but instead leave behind tiny, stable remnants. This challenges the traditional view that black holes disappear completely and addresses the black hole information paradox—a major conflict between Stephen Hawking’s theory of black hole evaporation and the laws of quantum mechanics. By suggesting that information is preserved in these remnants, the theory offers a new way to reconcile gravity with quantum mechanics, opening up exciting possibilities for understanding how the universe stores information.