Unified Quantification of Energy Dynamics in Stellar-Mass Black Holes
DOI:
https://doi.org/10.26821/IJSHRE.12.7.2024.120704Abstract
This study aims to provide a comprehensive analysis of energy dynamics within a stellar-mass black hole, focusing on the quantification of energy using a single variable. This research examines the processes of mass intake, photon behaviour, antimatter creation, and energy quantification in a black hole. Additionally, the process of accretion is explored, which details how celestial objects fragment into elementary particles due to intense gravitational forces. Gravitational lensing and red-shift effects on photons are analyzed to further provide a detailed foundation for the research while demonstrating the feasibility of anti-matter production through high-velocity quark collisions in the singularity’s vicinity. It quantifies the energy produced by matter-antimatter collisions, thus contributing to the black hole’s mass. Significant challenges which may hinder the scope of this research are also addressed, such as defining density at the singularity. Such a unified framework offers a fluid approach to understanding the black hole’s energy dynamics, providing a novel basis for future research.
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