The Mechanism of Supernova Explosions in the Framework of Cosmic Energy Inversion Theory CEIT from Core Collapse to Compact Object Formation

Supernova explosions represent one of the most dynamic cosmic phenomena, playing a fundamental role in the formation of heavy elements and galactic evolution. In this paper, we investigate supernova dynamics within the framework of Cosmic Energy Inversion Theory (CEIT), which introduces a dynamic space-time energy field where geometric torsion serves as the source of gravitational phenomena. We demonstrate that critical energy field gradients at the core-envelope interface of massive stars serve as the primary driver of core collapse and shock rebound formation. Our numerical simulations predict explosion energies on the order of 10^{47} erg, consistent with Type II supernova observations. Furthermore, we establish formation criteria for compact objects (neutron stars and black holes) based on energy field thresholds. This novel framework provides a unified explanation for explosion dynamics, matter ejection, and the cosmological implications of supernovae.