Quantum Gravity–Induced Neutron Superfluid Reaction Mechanism: A Potential High-Energy-Density Model

This paper proposes a neutron superfluid nuclear reaction model based on the quantum gravity modulation effect (QGM-NSR). The model assumes that in a strong equivalent gravitational field (simulated through a high-field-strength electromagnetic analog system), the coherence of the neutron wave function is enhanced, forming a quantum gravity-induced superfluid state, thereby triggering high-energy-density reaction processes. The modified Schrödinger equation incorporates a gravitational potential correction term ΔV_qg to describe the gravitational coupling behavior of the neutron wave function. Monte Carlo simulation results indicate that under conditions of equivalent gravitational acceleration |Φ_G|≈10⁻¹⁰ J/kg and neutron number density ρ = 10⁴⁴ m⁻³, the reaction rate peaks at approximately 10⁷ s⁻¹, with an energy density of about 10¹² J/kg, and the power spectral density exhibits 1/f characteristics, suggesting the emergence of self-organized criticality (SOC). The findings provide new insights into understanding the intersection between quantum gravity and condensed nuclear physics, and offer a theoretical basis for the future development of efficient nuclear energy.