The Impact of General Relativity on the “Inner Structure” within Atoms

The framework of Einstein's General Relativity, predicated on the curvature of spacetime induced by gravitational fields and the constancy of vacuum light speed, is increasingly subject to reinterpretation that challenges the established paradigm. This innovative perspective, rooted in the concept of "Equilibrium," posits the existence of variable light speeds at the intersections of coherent laser beams, thereby reshaping our comprehension of the five fundamental force densities associated with light. The research investigates the intricate interplay between gravitational phenomena and light across both astronomical and subatomic realms, delving into critical topics such as Gravitational Redshift, Black Holes, Dark Matter, and the complex dynamics governing light absorption and emission.Einstein himself cautioned against a literal interpretation of gravitational theory’s geometric aspects. Evidence of this can be found in his persistent reference to gravity as a force throughout his later works. Notably, in a letter dated April 8, 1926, he observed: “You are perfectly right. It is wrong to think that the ‘geometrization’ has significant meaning. It is only a kind of a clue helping us find numerical laws. Whether you connect a 'geometric' view to a theory is entirely a private matter.” Einstein (1926) [36].In stark contrast to General Relativity, this emergent viewpoint integrates the principles of gravity and light through a synthesis of the Stress-Energy Tensor and the Gravitational Tensor, illuminating the Gravitational-Electromagnetic Interaction. It proposes a tensorial framework for understanding Black Holes as Gravitational Electromagnetic Confinements, wherein the dynamics emerge from electromagnetic energy gradients and Lorentz transformations. By incorporating the "CURL" effect within the vicinity of Black Hole gravitational fields, this new theory demonstrates superior explanatory power relative to General Relativity, particularly in contexts such as Gravitational Lensing.Moreover, while Einstein’s contributions, including the Einstein Gravitational Constant within the Energy-Stress Tensor, represent a distinct approach, this new interpretation offers an integrated framework combining the Electromagnetic and Gravitational Tensors. The recent theoretical advancements regarding Black Hole solutions notably echo the seminal work of John Archibald Wheeler in 1955, which provided critical resolutions for the relativistic quantum mechanical Dirac equation within a tensorial context. Experimental validation of this paradigm shift is anticipated through the deployment of Galileo Satellites alongside ground-based MASER frequency measurements, revealing discrepancies between the predictions of General Relativity and the new theory, particularly concerning Gravitational Redshift and challenging observational limits.Additionally, the convergence of Quantum Physics and General Relativity—exemplified in frameworks such as String Theory—envisions dynamic natural constants. This interdisciplinary endeavour aspires to redefine understandings of the gravitational constant "G," asserting its temporal stability and facilitating a bridge between the domains of General Relativity and Quantum Physics.This abstract encapsulates pioneering research that elucidates the synergy between light and gravity within novel theoretical frameworks, alluding to potential breakthroughs poised to advance the fields of optical and gravitational sciences.