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Why are the hypothetical graviton particles so hard to detect?



Image 1) Elementary particles with hypothetical graviton. 


When we want to detect elementary particles we must remember that the elementary particles are so small. And some of them are so short-living that we don't have time to detect them. The particle itself doesn't vanish anywhere. It just turns to wave movement. If we are thinking that elementary particle has a form as wave movement and particle we must say that if we want to observe particles we want to observe those wave bites and especially their ball-looking forms.

 In the case of many massive high-energy particles, we cannot see those particles. We can see wave movement that those particles send. And when we are trying to think why we cannot see graviton we can start our chain of thoughts from another particle that is hard to detect. The name of that particle is Higgs boson. 

Higgs boson is a so-called scalar boson. The spin of the scalar boson equals zero. And that thing causes that it will not send wave movement. Or wave movement is so weak that it's hard to detect. If we want to compare that only known scalar boson with a cannonball that travels through the air. We can see that we are seeing only the quantum low-pressure area behind that boson. 

The reason why Higgs boson's spin equals zero is simple. In the case where the object's speed or energy level is extremely high. The Doppler effect pushes the quantum field to that particle. That thing acts like a pressure wave and the pressure of that quantum field is stopping the spin. 

But also that impacting quantum field will glide over the Higgs boson. That thing causes the effect where the outcoming Doppler-field impacts with Higgs boson's quantum field. And that impact wave denies that the radiation or wave movement that comes from the Higgs boson cannot come through that impact point. So the quantum field acts as the form of the stealth aircraft and makes the wave movement glide over the Higgs boson. 

Also, that impacting quantum field causes that there are no sideways coming wave movement that outside observer can detect. When we are thinking possibility that the pressure of a high-moving particle's quantum field can press them smooth. And turn their spin equal to zero we can think that the Higgs boson is rather the state of particle that some independent particle. But its behavior changes so much that we can say that it is an independent particle. 

There is the possibility that the Higgs boson spins so fast that it turns smooth. And smooth particles cannot send wave movement through the universe. That's why I believe that the black holes have no hair. And what is the hair of particle? The hair of the particle is the bites of waves or superstrings that are forming them. When the spin of particle turs fast enough or its gravitation field is strong enough. That pulls those hairs against the core of the particle. 



Image 2 introduces the impacting radiation when it impacts the black hole. But it could also introduce the behavior of the quantum field of the Higgs boson. The quantum fields or wave movement slide over that quantum field like they are acting in stealth aircraft. The name "Scalar boson" means that there is a possibility to turn all particles into scalar bosons simply by increasing their speed to a certain level. That thing makes those particles smooth. When we are thinking of wave-particle duality the particle is like a yarn ball. There are small hairs on that structure. 

And those structures or "hair" make normal particles rotate or spin because the wave movement touches those particles. But if the particle is smooth the outcoming wave movement cannot affect it. Or otherwise, we can think that the particle is rotating or spinning so fast. That the spin press those hairs against its core. If there is no hair that particle cannot send the radiation. The hair or the particle pushes the quantum fields and sends the wave movement moving through the space. If the particle is smooth or the quantum field denies that the other quantum fields cannot interact with the particle. That means there is no visible wave movement. 

But then let's go to think about the graviton. There is the possibility that the hypothetical transporter particle of gravitation is tensor. Or rather saying it's a tensor boson. In mathematics, tensor connects linear space, scalar descriptions, and certain geometric amounts. 

So we can think that the scalar boson closes all other bosons inside it. Or it involves all other bosons. And then we can continue this thinking that the tensor boson closes also the scalar boson inside it. That means it's so common but sends so weak radiation that it's hard to detect. The idea is that the tensor boson is in the middle of all other bosons. And that thing rolls the superstrings around it to yarn balls called particles. 

So when we are transforming that term to graviton it's hard to detect because it's inside all other bosons. The idea is that the graviton is like a pothole. There is the possibility that this hypothetical particle sends energy above it. That energy pike would aim the wave movement that it creates the cone that moves away from the graviton and if that cone is outside the pothole. That means that the graviton is like in shadow. And extremely hard to detect. 

And that thing makes it extremely hard to detect. When some radiation will travel against that graviton it travels over the pothole. There is the theory that graviton is a photon that has an extremely high energy level. That energy level will send the photon to the fourth dimension or turn it into a black hole.


If we think that photon is the ring-shaped superstring or bite of wave movement. We can think that the photon is the shockwave of the energy that comes from higher dimensions. When we are thinking about the fourth dimension. That thing is the energy level where material disappears from view. And then we can ask,  is graviton the point where the wave movement comes out from the fourth dimension?

So is the graviton particle a small tunnel between the fourth- and third dimension or the so-called white hole? The white hole is the point where the material comes out from the wormhole. The thing that makes white hole white is when those particles and wave movement are coming out from that energy channel. They are sending wave movement or the shock wave of white light. When material or wave movement drops from the fourth dimension it releases its energy level in the form of wave movement.


https://en.wikipedia.org/wiki/Doppler_effect


https://en.wikipedia.org/wiki/Four-dimensional_space


https://en.wikipedia.org/wiki/Graviton


https://en.wikipedia.org/wiki/Scalar_boson


https://en.wikipedia.org/wiki/Tensor


https://miraclesofthequantumworld.blogspot.com/

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