04 September 2025

Gamma ray transformation explained in Extended Classical Mechanics (ECM)

 A thought on the ECM principle:

Soumendra Nath Thakur | ORCiD: 0000-0003-1871-7803 | September 02, 2025
In a non-excessive gravitational environment, such as the periphery of a star like the Sun, gamma rays cannot persist for long durations. Their sustained existence appears to demand extreme gravitational conditions approaching the Planck scale, where only the highest-energy gamma rays remain viable. Near or beyond the Planck scale, however, the stabilization of energy appears possible only in plasma-like or collective energy-density structures, as isolated radiation modes become unsustainable.
Within ordinary stellar environments, gamma rays undergo interaction through a ΔMᴍ transformation: their excess mass–energy component (ΔMᴍ) energizes local electrons, which then re-radiate the energy as lower-frequency photons. In this sense, gamma rays effectively convert into photonic energy, reflecting ECM’s broader principle that ΔMᴍ transitions regulate the frequency-governed transformation of energy across different scales. This transition may be expressed compactly as:
KEᴇᴄᴍ = ΔMᴍc² = hf