Interdisciplinary Unification Theory Integrating Classical Mechanics, Electrodynamics, Quantum Physics, General Relativity, and Gravity-Light Interaction, Rooted in Newton's Foundational Principles

Newton's profound influence on the advancement of modern science is often underestimated. The comprehension of his seminal work, Philosophiæ Naturalis Principia Mathematica ("Mathematical Principles of Natural Philosophy"), initially published in 1687, poses a significant challenge for contemporary readers, even those well-versed in mathematics and physics. Subrahmanyan Chandrasekhar (1910-1995), the esteemed astrophysicist and Nobel laureate, dedicated the final years of his life to studying the Principia, striving to elucidate its complexities for modern physicists. Although Chandrasekhar could only delve into what he deemed as essential aspects before his passing, his endeavour underscores the formidable nature of Newton's magnum opus.Several factors contribute to the formidable nature of understanding the Principia. Firstly, Newton's use of geometrical (synthetic) methods, reminiscent of ancient Greek practices, contrasts with the algebraic (analytic) approach favored by contemporary scientists. This antiquated presentation style, compounded by the Latin language of the original text, hinders accessibility and pedagogy. Newton's employment of intricate geometrical proofs, rather than algebraic formulations, poses a substantial barrier to contemporary readers, as highlighted by William Whewell's observation of the formidable nature of Newton's intellectual arsenal.Additionally, Newton's aversion to controversies and his intentional esotericism aimed at discouraging superficial engagement further obfuscate the Principia's content. Amidst persistent criticism and hostility from various quarters, Newton maintained a rigorous technicality to deter detractors lacking genuine understanding. Despite potential criticism of Newton's approach, the intellectual environment of his era necessitated such guardedness, reflecting the challenges he faced in disseminating his groundbreaking ideas.Finally, the breadth and depth of Newton's contributions to mathematics and physics present formidable obstacles to readers. The Principia not only formulates fundamental laws of motion but also leverages Newton's pioneering calculus to derive Kepler's laws of planetary motion and elucidate celestial phenomena surpassing modern undergraduate education in physics and astronomy. Moreover, Newton's insights into fluid dynamics, optics, and acoustics, alongside his experimental prowess, underscore his multifaceted brilliance and enduring relevance in scientific discourse.While Newton's classical mechanics may not capture the entirety of contemporary scientific understanding, it remains a cornerstone upon which subsequent advancements, including relativity and quantum mechanics, have been built. Newton's legacy endures in the foundational principles and methodologies that continue to shape scientific inquiry, ensuring his enduring influence on the pursuit of knowledge.This groundbreaking Unification Theory at the forefront of physics and astronomy presents a comprehensive framework that integrates Classical Mechanics, Electrodynamics, Quantum Physics, General Relativity, and the intricate relationship between Gravity and Light. This theory delves into the profound interplay between gravity and light across both cosmic and sub-atomic scales, addressing phenomena such as Gravitational RedShift, Black Holes, and Dark Matter, as well as the nuanced dynamics of light absorption and emission at discrete energy levels within atomic structures. The new groundbreaking theory in physics has been intricately woven into the foundational fabric laid by Isaac Newton's seminal work in physics, “Philosophiæ Naturalis Principia Mathematica”.Diverging from conventional General Relativity paradigms, this theory introduces a novel concept involving the amalgamation of the "Stress Energy Tensor" and the innovative "Gravitational Tensor" to elucidate the Interaction between Gravity and Light. Notably, it offers a sophisticated mathematical Tensor formulation to elucidate the intricate mechanisms underlying Black Holes, particularly emphasizing the intricate Gravitational-Electromagnetic Interactions within these celestial entities, leading to paradigm-shifting insights into Gravitational Electromagnetic Confinements.By synthesizing the Electromagnetic Tensor with the Gravitational Tensor, this theory challenges existing notions surrounding the interplay of gravity and light, unveiling profound insights into phenomena such as the Gravitational Field surrounding Black Holes and the enigmatic Gravitational Lensing effects, phenomena that remain elusive within the realm of traditional General Relativity.