Could event horizon transform gravitational waves into electromagnetic wave movement?

  Could event horizon transform gravitational waves into electromagnetic wave movement? 

The event horizon of the black hole is the point where there is no return. After that, the particle must travel faster than the speed of light. And that thing is impossible. When we think that the event horizon is the extremely powerful Van Allen belt and the particles that fall through it interact with high-energy particles that are orbiting singularity in that point, we must understand that this point could be the X- and gamma-ray radiation source. 

Or if we think that the gravitational and magnetic fields look similar. But they are at different energy levels. That thing makes it possible. That there is a hole in the event horizon or black hole's gravitational field. 

The gravitational waves are interacting with each other. That interaction means that if there is a donut-shaped standing gravitational wave at the point of the event horizon. That standing gravitational wave can pull other gravitational waves out from the internal structures in the black hole's event horizon. 

"When black holes collide, they produce gravitational waves detectable on Earth. Although theorized by Einstein in 1916, they were not directly observed until 2015. Modern research contrasts older models with new data, revealing that these waves do interact. This knowledge refines our models and challenges the full scope of general relativity in explaining black hole properties". (ScitechDaily.com/Ripples in Spacetime: Unraveling the Secrets of Gravitational Waves)

That means. There could be a stronger gravitational area at the black hole's event horizon's outer shell at the point where the acceleration disk falls in the black hole. At that point, the acceleration disk sends wave movement to the point of the event horizon. And that makes this hypothetical gravitational wheel possible. At that point particles that orbit singularity are at higher energy levels than other places in the event horizon. 

In that case, there is a possibility, that a black hole pulls wave movement and particles to impact course with particles. That is trapped in the event horizon or the point where escaping velocity reaches the speed of light. This impact can cause a similar effect with solar wind or particles that impact plasma trapped in the Van Allen belt.  

The event horizon could be like a more powerful version of the sonic whirl. In the event horizon, the speed of particles is the minimum speed of light. Below it, the photons and all other particles travel at the same speed, which is higher than the speed of light outside the event horizon. 

But if a particle orbits singularity precisely at the point of the event horizon the incoming gravitational waves may impact with particles or superstrings. And that thing loads energy to them. In that position, the speed and energy levels of the impacting particles are much higher than in sonic whirls or Van Allen plasma belts. 

So, could it be possible that the particle, trapped in the point of the event horizon can transform gravitational waves' wavelength into electromagnetic radiation? 

The position where gamma- and X-ray bursts leave from the black hole is interesting because it can open a route to the new world. Black holes can trap particles and superstrings in the event horizon. And it's possible that if some wave movement or superstring impacts with superstring or particle in the event horizon. That thing can turn the wave movements wave length from, for example, gravitational waves to electromagnetic waves. 

This means that. The event horizon or superstrings that travel in it could turn the gravitational waves straight to electromagnetic wave movement. The idea is that the superstrings that travel to the point of the event horizon will just jump up from that point when gravitational waves from inside the black hole impact it. That impact raises the superstring just out from the point of the event horizon. 

https://scitechdaily.com/ripples-in-spacetime-unraveling-the-secrets-of-gravitational-waves/