Pinčák Team Proposes 7-Dimensional Black Hole Remnants, Storing 1.515×10^77 Qubits
Updated
Updated · SciTechDaily · Jun 1
Pinčák Team Proposes 7-Dimensional Black Hole Remnants, Storing 1.515×10^77 Qubits
2 articles · Updated · SciTechDaily · Jun 1
A new General Relativity and Gravitation study argues black holes do not fully evaporate but end as stable remnants, offering a route around Hawking’s information-loss paradox.
In the team’s seven-dimensional Einstein-Cartan model, spacetime torsion turns repulsive at Planck-scale densities, halting final collapse and leaving a remnant with a predicted mass near 9×10^-41 kg.
Those remnants would preserve infalling information in torsion-field quasi-normal modes; a remnant from a Sun-mass black hole could encode about 1.515×10^77 qubits, according to the calculations.
The same geometry also yields the electroweak scale of about 246 GeV when reduced from seven dimensions to four, linking the black-hole mechanism to the Higgs-related mass hierarchy problem.
Direct collider tests look remote because associated Kaluza-Klein states are estimated near 8.6×10^15 GeV, but the paper points to possible signatures in dark matter, the cosmic microwave background and primordial gravitational waves.
Is dark matter a cosmic archive of information, stored in the remnants of dead black holes?
Are black holes immortal vaults that store information, rather than cosmic data shredders?
Does a new 7D theory reveal that particle mass is just a side effect of gravity?
Resolving the Black Hole Information Paradox: Stable Remnants, Extra Dimensions, and the Higgs Connection (2026 Breakthrough)
Overview
For decades, scientists have struggled with the black hole information paradox, which arises because Stephen Hawking's theory predicts black holes evaporate and disappear, seemingly destroying information—a direct conflict with quantum mechanics, where information must be preserved. A new 2026 study offers a breakthrough by proposing that black holes never fully vanish but instead leave behind ultra-tiny, stable remnants that store all the information they consumed. This idea bridges the gap between gravity and quantum theory, suggesting a way to resolve the paradox and uphold the fundamental laws of physics.