Coherent Nuclear Fusion via Topological Reconnection in a Chiral Superfluid Vacuum: Overcoming the Coulomb Barrier at Cryogenic Temperatures and High Magnetic Fields

Traditional approaches to controlled nuclear fusion rely on overcoming the Coulomb barrier through high temperatures (thermonuclear fusion), resulting in stochastic processes characterized by low efficiency and significant technological hurdles. This paper presents an alternative theoretical framework based on the V4DS (Universe as a 4D Superfluid) model, wherein nucleons are interpreted as stable quantized vortex rings within an incompressible, chiral vacuum of zero viscosity. In this model, the Coulomb barrier is not a fundamental force but a manifestation of hydrodynamic turbulence between rotating defects. We propose that controlled fusion of light nuclei can be achieved deterministically under conditions approaching absolute zero (T→0 K) and in the presence of a strong homogeneous magnetic field. Cryogenic temperatures suppress thermal vacuum noise (phonon excitations), while the magnetic field ensures topological polarization (parallel alignment of spin/vortex axes). Under these conditions, fusion occurs not via high-energy collision, but through spontaneous topological vortex reconnection, an energetically favorable process leading to the emission of coherent radiation rather than thermal chaos.