The prevailing view in physics today is that time is relative, dilating in response to velocity and gravitational fields. Version 2.0 of this theoretical framework extends this model by introducing a third axis of relativity: the physical scale. The fundamental postulate states that time is a multidimensional phenomenon, and its passage is inversely proportional to the spatial scale of the system. Using timescale dilation, this paper offers a deterministic and mechanistic explanation for subatomic energy generation. Subatomic particles (such as electrons) do not defy classical mechanics; rather, they exist in an extremely compressed timescale. One day at the macroscopic level translates into billions of years of internal processing time for a subatomic particle. Thus, the enormous energy released in nuclear or electromagnetic events is not simply a mass transfer, but a sudden release of energy at the macroscopic level, accumulated over a vast and compressed subatomic timescale. Key contributions in version 2.0: Derivation of the timescale factor, which links macroscopic observation with microscopic timescale frequency. The mathematical solution to the "electricity" paradox between Earth and the electron. * Redefining the Lorentz factor as a function of spatial scale. A mechanical framework that resolves quantum tunneling and wave-particle duality as time-delay phenomena in observation. Have you ever wondered why the subatomic world of atoms seems so strange and frightening compared to our everyday physical world? For a century, science has told us that particles can be in two places at once and move in unpredictable ways. This research, "timescale relativity," proposes a simpler, more logical explanation: The universe operates on different timescales depending on the size of the object. Key takeaway: Time is not a cosmic constant. Just as a slow-motion camera reveals the finest details in a scattered water droplet, the subatomic world simply operates at a frame rate far beyond what our human eyes can perceive. We've calculated that one second in our universe is roughly equivalent to a thousand years for an electron. Solving ancient mysteries: The energy puzzle: Why do tiny atoms possess enough energy to destroy cities or power entire countries? Because it accumulates energy over long periods of time. What we perceive as a moment of heat is, for the particle, a thousand years of energy absorption. The electrical paradox: Why does the Earth's immense rotation generate no energy, while a tiny electron generates electricity? It all comes down to frequency. The electron spins trillions of times per second, exceeding a threshold that activates the electromagnetic field. The "ghost" particle: Particles are not "ghosts" existing in two places at once. They move at extremely high speeds along their own timeline, making them appear blurry to us, much like a hard drive's rapidly spinning fan. Proving the theory: This paper goes beyond mere theorizing; it presents a mathematical blueprint for experiments using ultra-precise atomic clocks and nanoscale confinement to demonstrate that time literally moves at different speeds within a compressed space. We don't live in a "scary" or "strange" universe. We live in a logical, mechanical universe, where the only thing separating us from the secrets of the atom is a difference in the "speed" of time.
Abdul Moneim Mohammed Attia (Wed,) studied this question.