The black hole information paradox stands as one of the most intractable puzzles in contemporary theoretical physics, arising from the conflict between quantum mechanics’ unitarity (information conservation) and general relativity’s prediction of causal isolation at the event horizon. This paper proposes a unified solution based on a radical yet logically consistent first principle: the Instantaneous Teleportation Cosmos (ITC), where zero-latency transmission of matter, information, and energy is possible between any two spacetime points in the universe. The instantaneous teleportation mechanism establishes direct non-local connections between the interior of a black hole and the external universe, eliminating the event horizon as an absolute causal boundary. Information trapped inside a black hole can escape either directly through zero‑latency channels or be encoded into Hawking radiation, thereby ensuring information conservation without violating quantum mechanics or causal laws. Based on the ITC theory, we predict that information leakage occurs already in the early-stage of black hole evaporation, accompanied by observable non‑thermal features: discrete spectral lines from direct escape and quasi-periodic modulations from information encoding. These non‑thermal features, which deviate from a perfect thermal spectrum, can all serve as detectable physical signals. With the advancement of observational technologies in the future, high-precision measurements of the evaporation process of primordial black holes are expected to accurately capture these characteristic signals. This would provide direct observational evidence for the existence of instantaneous teleportation and the validity of the ITC theory, while also offering verifiable experimental support for the resolution of the black hole information paradox.
Lei Ding (Sat,) studied this question.