Author(s)

Hung-Te Henry Su^1*, Po-Han Lee^2,3*

¹Department of Physics, CCU, Chia-Yi.
²Department of Electro-Optical Engineering, Taipei Tech, Taipei City.
³The Affiliated Senior High School of NTNU, Taipei City.

In this study, we propose a novel theoretical framework for the manipulation of gravitational-photonic (g-photon) fields via aluminum-based resonant stabilizer structures. Grounded in the principles of vacuum curvature engineering, we examine the interaction between quantized graviton-like photon modes and the K-shell electronic transition energy of aluminum (~1.52 keV). We hypothesize that this resonance condition enables localized stabilization of graviton beams, thereby facilitating coherent remote manipulation of matter—a process analogous to a gravitational tractor beam. By integrating quantum field-theoretical modeling with Casimir-like negative energy phenomena, we outline a prospective approach for remote mass manipulation in extraterrestrial environments. Theoretical analysis supports the feasibility of graviton-photon coupling mediated by the atomic configuration of aluminum. The implications of this mechanism are discussed with respect to advanced propulsion technologies, quantum teleportation architectures, and gravitational shielding applications, providing a foundation for future spacecraft systems capable of non-contact extraction of material and biological targets from planetary surfaces.

Gravitational-Photonic Fields, Graviton-Photon Coupling, Aluminum-Based Resonant Stabilizer, Vacuum Curvature Engineering, Casimir-Like Negative Energy, Quantum Field Theory

Su, H.-T.H. and Lee, P.-H. (2025) Development of a Graphene-Axion System via the K-Shell Transition of Aluminum: A Stabilization Mechanism for Graviton Emission in the Higgs Fields. Journal of High Energy Physics, Gravitation and Cosmology, 11, 1052-1063. doi: 10.4236/jhepgc.2025.113068.