Quantum gravity is a critical area of research aiming to reconcile the principles of general relativity and quantum mechanics. While general relativity explains the gravitational forces acting on massive bodies, it lacks compatibility with quantum mechanics, which governs the behavior of subatomic particles. This paper explores the implications of quantum gravity for photon behavior, particularly focusing on energy transformations and dimensional shifts. Previous works, such as those by Author A (2018) and Author B (2020), have explored these interactions but have yet to fully explain the role of gravitons in the energy cycles observed in high-gravity fields. Quantum gravity remains one of the greatest unsolved problems in physics. Efforts like string theory and loop quantum gravity aim to unify gravity with the quantum world. This research contributes to those efforts by examining how quantum mechanics and gravity interact in high-energy systems, particularly focusing on photon-graviton interactions in extreme environments such as black holes and gravitational lenses.The author acknowledges the use of OpenAI’s language model for assistance in drafting certain sections of this workl