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Abstract
This paper presents a theoretical framework exploring the possibility of a super-Penrose process within Schwarzschild black holes by incorporating quantum entanglement phenomena described by Bell's Theorem. By extending the classical Penrose mechanism and introducing quantum non-locality, the feasibility of energy extraction under extreme collision conditions near the event horizon is discussed. The study combines classical particle dynamics with quantum entangled states to investigate the potential impact of quantum non-locality in black hole physics. Advanced mathematical formulations and physical models are provided to elucidate the energy collision mechanisms under stringent conditions, evaluating the theoretical upper limits of energy extraction and their physical significance. The results suggest that the hypothesized super-Penrose process may theoretically achieve higher energy extraction efficiency than the classical Penrose process, although its realization requires further theoretical validation and experimental support.