Within the realm of astronomy and astrophysics, the profound connections between Black Holes, Dark Matter, and the intricate interplay among light, gravity, and electromagnetic forces continue to captivate researchers. Building upon the foundational tenets of Einstein's General Relativity, which elucidate the curvature of spacetime under the influence of gravitational fields and uphold the constant speed of light in vacuum, a fresh perspective emerges.This novel viewpoint pivots on the concept of "Equilibrium" governing the five fundamental force densities in light, suggesting dynamic variations in light speeds when coherent laser beams intersect. This departure from the conventional assumption of a constant light speed challenges the core principles, Einstein Albert (1953), of General Relativity, prompting a thorough investigation into the gravitational and luminous interactions at both celestial and sub-atomic scales. The exploration extends across diverse phenomena, encompassing Gravitational Redshift, Black Holes, Dark Matter, and the intricate processes of light absorption and emission on a microscopic scale.In contrast to the established framework of General Relativity, this innovative perspective seeks to merge the realms of gravity and light through a harmonious amalgamation of the Stress-Energy Tensor and the Gravitational Tensor. This union not only sheds light on the nuanced interplay between gravity and electromagnetism but also unveils a novel tensor representation for Black Holes termed as Gravitational Electromagnetic Confinements. By integrating electromagnetic energy gradients and Lorentz transformations, this approach transcends the traditional boundaries of General Relativity, particularly evident in scenarios of Gravitational Lensing.The reinterpretation of Einstein's foundational work, Einstein Albert (June 21, 1911), featuring the Einstein Gravitational Constant within the Energy-Stress Tensor, introduces a combined Electromagnetic Tensor and Gravitational Tensor framework. Theoretical advancements in Black Hole solutions resonate with the pioneering spirit of Jonh Archibald Wheeler's work in 1955, providing essential solutions for the relativistic quantum mechanical Dirac equation within a tensor formalism. Experimental validation of this paradigm shift, combining data from Galileo Satellites and ground-based MASER frequency measurements, underscores the disparities between General Relativity and the proposed New Theory, pushing the boundaries of gravitational observations to unprecedented accuracies.The synergy between Quantum Physics and General Relativity theories, as exemplified by approaches like String Theory, anticipates variances in natural constants. This interdisciplinary pursuit aims to redefine our understanding of the gravitational constant "G," illuminating its timeless constancy while bridging the domains of General Relativity and Quantum Physics.This abstract encapsulates the essence of groundbreaking research unfolding at the intersection of light, gravity, and theoretical frameworks within the realm of astronomy and astrophysics, offering tantalizing prospects for transformative discoveries at the forefront of optical and gravitational sciences