Why wavelength of wave movement is important? All particles send wave movement that wavelength is the same as their size. Another question is why is the frequency of wave movement important? Frequency determines how often a particle sends wave movement. And that gives information about the size of the particle.
If a particle sends wave movement with a short wavelength very often. That means the particle is very small. Wave movement or large-scale waves are energy fields that are leaving particle groups. In this model, particles send wave movement. While they travel as the front in space. The wave movement is traveling the power field.
When wave movement travels through other wave movement or power field that has the same wavelength and frequency. The recessive power field impacts energy to a higher power energy field. Things like electric arcs are standing waves. And we can think that things like black holes are somehow similar effects to electric arcs. But the frequency and wavelength of that energy is different.
In regular versions of electric arcs, electromagnetism forms those standing waves. And we could call those things like black holes gravitational versions of electric arcs. Or gravitational waves should be able to make standing waves. The gravitational waves are the things that give new types of information about the universe, and its supermassive objects.
"Chinese scientists has recently found key evidence for the existence of nanohertz gravitational waves, marking a new era in nanoHertz gravitational research. Credit: Image by CAS New Media Lab". (ScitechDaily.com/Probing the Universe’s Secrets: Key Evidence for NanoHertz Gravitational Waves)
"FAST helps find key evidence for the existence of nanohertz gravitational waves with its high sensitivity. Credit: Image by NAOC of CAS", (ScitechDaily.com/Probing the Universe’s Secrets: Key Evidence for NanoHertz Gravitational Waves)
"The Chinese Pulsar Timing Array (CPTA) collaboration has identified evidence of nanohertz gravitational waves using the Five-hundred-meter Aperture Spherical Radio Telescope (FAST). Despite their shorter data set, their high sensitivity yielded results comparable to other international groups. This discovery is pivotal in understanding the Universe’s structure and behavior of supermassive black holes, paving the way for future exploration of gravitational waves". (ScitechDaily.com/Probing the Universe’s Secrets: Key Evidence for NanoHertz Gravitational Waves)
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The singularity and how it interacts with gravitational waves?
In the middle of a black hole is the material called the singularity. That material is the combination or entirety of time and space. There is no space where energy can go. Gravitation pulls superstrings to the flat. The information that comes outside the event horizon will pack around the singularity.
Sooner or later, the energy level of that wave movement turns higher than the energy level of the wave movement. That comes out from the event horizon. That wave movement will start to push the standing gravitational waves outside the center of the black hole.
Whenever material and wave movement increases or decreases. That thing causes changes in energy stability in the black hole. When that stability changes. The position of the standing wave inside the event horizon changes. And that causes changes in radiation levels that can come out from the black holes. So that thing is the wave motion that is seen as gravitational waves.
In models, the singularity is extremely slight. So it sends straight wave movement that affects the outcoming wave movement. The reason why this wave movement affects all other wave movements is that it's so dense.
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There are models that inside the singularity of the black holes is a small space where superstrings are not connected. There is no gravitation at that point. That space is smaller than a quark. But the gravitational waves are traveling through it. And then that thing makes the black hole's nucleus or singularity oscillate and sends wave movement against the information that travels in the event horizon.
The surprising and wonderful thing in this model is the reflecting radiation. That comes out from the singularity. The special form of singularity is that it cannot take radiation or wave movement to any place. There is no free space in that form of material. And gravitation pulls even superstrings flat. So the black hole packs wave movement around that complicated structure of the entirety of material, time, and space.
When wave movement is packed around the singularity. Its energy level rises. The radiation impacts the wave movement that comes out from the event horizon. Energy always travels to a lower energy level. And sooner or later the energy level around singularity turns so high that it can push radiation through the event horizon.
https://scitechdaily.com/probing-the-universes-secrets-key-evidence-for-nanohertz-gravitational-waves/?expand_article=1
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