Can a Möbius Twist Solve the Black Hole Information Paradox?

Twisting the Black Hole Information Paradox

Imagine your computer's hard drive is a strip of paper. If you twist that paper once and tape the ends together, you get a Möbius strip—a loop with only one side. This simple geometric trick may explain what happens to data swallowed by a collapsed star.

For decades, physicists have clashed over the black hole information paradox. Quantum theory insists that physical information cannot be destroyed, whilst general relativity suggests gravity destroys it forever. Now, an early-stage preprint awaiting peer review suggests space-time might have a twisted, Möbius-like structure that prevents this loss.

A Mathematical Reflux Gate

The preliminary model suggests that as matter crosses an event horizon, it enters a "quantum reflux zone". In this region, three-dimensional structures dissolve into pure quantum states. Instead of vanishing, the information is topologically recycled back into a pregeometric void, potentially seeding new cosmic cycles.

To support this framework, the researchers analysed how their dimensional equations behave in other systems. They measured a striking alignment across several fields:

• Predicting superconducting temperatures in twisted graphene.
• Mapping critical transitions in plant-defence densities.
• Calculating soil-carbon stabilisation thresholds.

While these cross-disciplinary links are highly preliminary, they suggest a universal law of dimension that connects cosmic-scale physics to biological systems.