Quantum Entanglement as Phase Coherence in a Superfluid Energy Field

We propose a physical interpretation of quantum entanglement within the framework of the Superfluid Energy Field (SEF), in which the quantum vacuum is modeled as a coherent medium described by a complex scalar field. Within this approach, spacetime, matter, and interactions emerge as collective and topological properties of a single underlying field. We show that entanglement can be understood as a manifestation of long-range phase coherence in this medium. Spatially separated systems correspond to localized excitations embedded within a single, non-factorizable field configuration, and their correlations arise from the global structure of the phase rather than from dynamical nonlocal interactions. This interpretation provides a natural explanation for the violation of Bell inequalities while preserving relativistic causality. The no-signaling theorem is maintained through a clear distinction between global coherence and local dynamical evolution, while decoherence is reinterpreted as the loss of long-range phase coherence leading to the emergence of classical behavior. The framework is constructed to remain fully compatible with the empirical predictions of quantum mechanics at the effective level, while suggesting the possibility of small deviations associated with the finite coherence properties of the underlying field. These results support the view that quantum correlations may arise from the coherence of a continuous physical medium, thereby providing a unified hydrodynamic perspective on quantum phenomena.