The Influence of Gravity on the Speed of Light within Black Holes

Understanding the interaction between gravity and light in the vicinity of black holes remains a fundamental question in theoretical and observational astronomy. The behavior of light near these enigmatic cosmic entities has profound implications not only for quantum physics but also for our broader comprehension of the universe.

Black holes, characterized by their intense gravitational fields, have captured the imagination of scientists and laypersons alike. According to D.J.Longenhagen's unique perspective, gravity is fundamentally driven by photons. This perspective opens up a new avenue to explore the dynamics of black holes and the behavior of light within them. Longenhagen suggests that gravity, as an effect caused by an exotic mass, behaves instantaneously and can be understood through the lens of photon physics.

Gravity as a Photonic Phenomenon

Longenhagen posits that gravity is essentially a photonic force acting instantaneously across space. The strength of this gravitational field is dependent on the density of photons in a given area. In his model, two photons in close proximity repel each other, and this repulsion is amplified by the exotic mass. The rotation of a black hole's mass can be attributed to this photonic repulsion, with the speed of rotation influencing the path of the gravitons (or light) as it approaches the event horizon.

The Role of Photonic Physics in Black Hole Dynamics

According to Longenhagen, the speed of light within a black hole is not constant. As light approaches the event horizon, it experiences a gradient of gravitational "pull." This gradient, which can be perceived as a "push" from the quadrillions of gravitons, is crucial in understanding the behavior of light near the event horizon. The event horizon, as described by Longenhagen, appears as light zipping at almost a 90-degree angle to the mass surface below, altering its speed based on the proximity to the black hole's gravitational center.

Gravitational Forces and Photonic Density

The dynamics of photon density play a significant role in the behavior of light within a black hole. The poles of the black hole experience the least photon density, while the equator has the highest density. This gradient in photonic density results in an apparent slowdown of light speed near the poles and a faster approach to the event horizon near the equator. These variations in light speed create complex patterns as light navigates the intense gravitational field of a black hole.

The Age of a Black Hole and Rotation Velocity

The rotational velocity of a black hole's mass is quantized at the subnucleic level, leading to a balanced rotation akin to a dynamical flywheel. This flywheel effect conserves rotational velocity, causing the event horizon to transition from a spherical shape to an oblong spheroid. This transition reflects the age of the black hole and can be used as a method to estimate its history and evolution. As the rotational velocity approaches the speed of light, jets of degenerate matter are ejected from the poles, marking the black hole's end of life.

Theoretical Implications and Future Research

Longenhagen's theory suggests that a device capable of faster-than-light (FTL) travel could potentially bypass the event horizon and retrieve information from beyond. This concept challenges current understanding and invites further exploration. The theoretical limits of black holes, as defined by the Hopf fibration algorithm, provide a framework for understanding the mass ejection process, particularly the jets of degenerate matter emanating from the poles. The reconstitution of subatomic matter back into hydrogen could signal the termination of a black hole's life cycle and the return to standard physics.

While Longenhagen's model is primarily theoretical, it offers a novel perspective on the behavior of light and gravity within black holes. Future research in this field could refine these theories and potentially validate them through advanced observational techniques and simulations.