New Developments and Insights into the Black Hole Light-absorption Mechanism

The Weitzenbock spacetime supports the idea that black holes can absorb electromagnetic energy and expand. This explains black hole expansion. This principle is essential to understanding black hole growth. This space-time is distinguished from others by its torsion tensor, which is made of four parallel vector fields. A unique feature of this space-time. Another characteristic is absolute parallelism, or the vanishing curvature tensor. Parallel vector fields form both tensors, with the other as its major component. This essential element creates tensors. Both features must be considered and analyzed to fully characterize Weitzenbock space-time. To successfully integrate the idea that black holes absorb light, it must be established. The theory has been called "new general relativity" since Einstein introduced it in 1928 and remains the dominant framework for its description. The recently developed General Theory of Relativity includes c1, c2, and Einstein's constant. Recently, the General Theory of Relativity was built. The speed of light in a vacuum, c1, differs from c2 in other media. The velocity of light in a vacuum is c2, not c1. It is better for the study to assume c1,c2 →∞, which will produce an unpredictable result. We decided such action was best for us. This lets us handle this investigation in a way that benefits both parties. This paper shows three key findings: the Schwarzschild metric describes a static and spherically symmetric gravitational field; the weak-field approximation includes an antisymmetric field with zero mass and spin and gravitons; and the newly developed general theory of relativity matches all experimental results.