Unification of the Fundamental Equations in Physics: A Single Functional Relation Between Mass and Volume
Nishant Sahdev1, Chinmoy Bhattacharya2
1Nishant Sahdev, Department of Physics, University of North Carolina at Chapel Hill, US, India.
2Chinmoy Bhattacharya, Austin Paints & Chemicals Private Limited, 3 Ambika Mukherjee Road, Belghoria, Kolkata (West Bengal), India.
Manuscript received on 26 July 2025 | First Revised Manuscript received on 08 August 2025 | Second Revised Manuscript received on 27 September 2025 | Manuscript Accepted on 15 October 2025 | Manuscript published on 30 October 2025 | PP: 14-25 | Volume-5 Issue-2, October 2025 | Retrieval Number: 100.1/ijap.B106605021025 | DOI: 10.54105/ijap.B1066.05021025
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Abstract: Since the inception of classical physics, scientists worldwide have continually introduced new equations. Notably, the three fundamental physical variables—mass, time, and temperature—have consistently played central roles in these formulations. However, these variables are often treated as ‘abstract’ quantities, particularly because their physical dimensions, about length (L), have seldom been explicitly addressed. In this research, a novel thermodynamic approach has been employed to investigate the dimensional relationships between time (t), mass (M), and temperature (T) and length (L). The new dimensions revealed for these variables have the potential to reshape both modern and classical physics. The equation mass = density × volume holds profound significance in physics. Density, in this context, serves as an indirect measure of a material’s cohesiveness, or orderliness; among materials of varying density, the one with the greater density will house more molecules within a fixed volume, and is thus more cohesive. Density is, therefore, an index of order. Conversely, increasing the volume of a given mass—such as by introducing air voids or foams—decreases density, thereby diminishing cohesiveness and increasing disorder or randomness. Density, then, is the “creator” of order, while volume gives rise to disorder or randomness. Thus, mass, being the product of density and volume, is inherently a composite variable that embodies both order and disorder. This article demonstrates that the contribution of density (order) outweighs that of volume (randomness), making mass, as a hybrid parameter, primarily indicative of order. Every physical, mechanical, or chemical process is fundamentally an interplay of order and disorder, manifested in the equation mass = density × volume. Core principles of physics—including the laws of motion, mass-energy equivalence, ideal gas behaviour, wave-particle duality, the uncertainty principle, and the quantum mechanics of microscopic particles—can all be understood as manifestations of these order–disorder phenomena. Consequently, all fundamental equations in physics may ultimately converge upon, or be unified with, the relation mass = density × volume. Such unification or convergence can only be fully understood once the three principal variables—mass, time, and temperature—lose their abstraction and are properly embodied. In this research, we offer a foundational embodiment for these variables, opening new horizons for modern physics.
Keywords: Dimensional Analysis, Mass-Volume Relation, Unified Physical Equations, Thermodynamic Compactness & Hard-Core Volume (HCV).
Scope of the Article: Mathematical Physics