Lattice-Confined Phonon-Enhanced Quantum Tunneling (LCPEQT): A Novel Mechanism for Low-Temperature Nuclear Fusion in Condensed Matter Systems

We propose a novel mechanism called Lattice-Confined Phonon-Enhanced Quantum Tunneling (LCPEQT), that combines three established quantum phenomena to enable nuclear fusion at approximately 100°C in engineered metal hydride lattices. By using enhanced electron screening in metallic environments, coherent phonon-mediated energy transfer, and lattice-confined quantum tunneling, we predicted a reduction in the Coulomb barrier tunneling exponent from ~2800 (essentially impossible) to ~23.4 (measurable). This represents a 10⁷-10⁹× enhancement in tunneling probability while respecting fundamental physics principles. We present the theoretical framework, detailed experimental protocols, and testable predictions for validating or falsifying this hypothesis. This work bridges condensed matter physics, nuclear physics, and materials science to explore fundamental limits of quantum tunneling in confined system. only visualization guide is made using taking help of ai .