lobal Journal of Science Frontier Research, A: Physics and Space Science, Volume 24 Issue 4

Fig. 1: The Energy Density [ J/ m3] as a function of the Radius R = max 107[m] of the Black Hole Fig. 2: The Energy Density [J/ m3] as a function of the Radius R = max 105 [m] Figures 1 and 2 showcase the significant impact of "Gravitational Intensity Shift" and "Gravitational RedShift" at a distance of 25 km. Over a distance of 10,000 km, the intensity of light emitted by a Black Hole with a mass of 10 35 kg decreases by a factor of 10 -51 . Similarly, the frequency of the emitted light from the Black Hole decreases by a factor of 10 -51 . For instance, light emitted in the visible spectrum at 10 14 Hz drops to a frequency of 10 -37 Hz. These extremely low frequencies with minimal intensities have not been observed, leading to the term "Black Hole" being used to describe the phenomena of "Gravitational Intensity Shift" and "Gravitational RedShift" in the presence of a massive object. According to equation (8) and solutions (10) and (11), it is deduced that the speed of light remains constant within and around a Black Hole. The only potential change is in the direction of light propagation due to the influence of a gravitational field. c) Dark Matter in the Universe controlled by “Gravitational Shielding” Fig 3 represents Dark Matter with a total mass of 10 53 [kg] and a radius of about 10 times the size of the Milky Way Galaxy. The radius of the dark mass equals 5 10 21 [m] which has been controlled by a different mathematical solution (20) for equation (8). [ ] 3 BH 0 0 G M ε μ - log[r] 8 π r [J / m ] e f r K       = (20) Global Journal of Science Frontier Research ( A ) XXIV Issue IV Version I Year 2024 53 © 2024 Global Journals A Reinterpretation of Quantum Physics