More about Fayman's virtual photon and gravity
Fayman's virtual photon is a theorem, where a photon is moving zigzag trajectory, and if the zigzag-movement is long and thick enough, some other particle can go through photon. And in this case, another particle would reach the same target before photon, because photon moves the same route by using a longer trajectory, and this is the thing, what makes virtual photon so important. The thing is a virtual photon is that in the quantum world photons moving zigzag movement, but that movement is so small that we cannot meter that thing.
So what makes this theorem interesting. The thing is that the theorem of virtual photon bases the idea that gravity is an interactive force. The interaction between particles means that they are pulling together to each other. And gravity is the force that affects between particles. So Moon pulls Earth to it, in the same way, the Earth pulls Moon to it. And gravity is the thing that is the force of the material. Even the smallest particles in the universe have gravity fields. And that means they affect photons, what is traveling in the space, what we call the universe.
And that means photons are not moving by using straight trajectories because of every single hydrogen atom affects their trajectories. So if we can create a particle, what travels by using a straight trajectory, we can cross the speed of the natural photons, and then we must say that this kind of thing is impossible.
We would need a black hole in that test, and even if we would shoot photon to that black hole, crossing the speed of the natural photon is impossible. Black holes would pull all photons at that point, and that means every single photon around the black hole is dropping in the black hole the same speed with every other photon. This kind of thing has not very much benefit for people, who are working with that kind of question.
And the second thing is that we must have a black hole in our hands, that we can make that thing. If we would create a stable singularity in some laboratory, that thing can destroy the entire Earth, and also the entire solar system, if we release it in the wrong place. So if we would take the test, what happens if we shoot the photon to the black hole we must find the natural black hole. In the Cygnus X-1 is one well known individual black hole, and we can shoot photons to that object.
The distance of that object is 6197 light-years, and the thing that makes us believe that there is a black hole is that the target is a powerful X-ray transmitter. But we believe that is the black hole, and the only certain black hole, what we can surely say is a black hole or object what escaping velocity is higher than the speed of light is the center of the Milky Way.
So the distance to the center of our galaxy is 27000 (+-10000) light-years. And if we would send the laser ray to each of the targets, we can see what happens after 6197 or 27000 years, if we would use spacecraft, which travels by speed of light. Otherwise, we should wait two times longer if we want to get an answer, what happens when laser ray impacts to the black hole.
And the time to wait 123494 or 54000 years is a little bit long time. So what would we see, if we can follow the laser ray journey to that black hole? Maybe the laser ray would just disappear or it can turn back to us. But it cannot move faster than other photons. This makes theories so fascinating. Until they are proven wrong or right everything is possible.
Fayman's virtual photon is a theorem, where a photon is moving zigzag trajectory, and if the zigzag-movement is long and thick enough, some other particle can go through photon. And in this case, another particle would reach the same target before photon, because photon moves the same route by using a longer trajectory, and this is the thing, what makes virtual photon so important. The thing is a virtual photon is that in the quantum world photons moving zigzag movement, but that movement is so small that we cannot meter that thing.
So what makes this theorem interesting. The thing is that the theorem of virtual photon bases the idea that gravity is an interactive force. The interaction between particles means that they are pulling together to each other. And gravity is the force that affects between particles. So Moon pulls Earth to it, in the same way, the Earth pulls Moon to it. And gravity is the thing that is the force of the material. Even the smallest particles in the universe have gravity fields. And that means they affect photons, what is traveling in the space, what we call the universe.
And that means photons are not moving by using straight trajectories because of every single hydrogen atom affects their trajectories. So if we can create a particle, what travels by using a straight trajectory, we can cross the speed of the natural photons, and then we must say that this kind of thing is impossible.
We would need a black hole in that test, and even if we would shoot photon to that black hole, crossing the speed of the natural photon is impossible. Black holes would pull all photons at that point, and that means every single photon around the black hole is dropping in the black hole the same speed with every other photon. This kind of thing has not very much benefit for people, who are working with that kind of question.
And the second thing is that we must have a black hole in our hands, that we can make that thing. If we would create a stable singularity in some laboratory, that thing can destroy the entire Earth, and also the entire solar system, if we release it in the wrong place. So if we would take the test, what happens if we shoot the photon to the black hole we must find the natural black hole. In the Cygnus X-1 is one well known individual black hole, and we can shoot photons to that object.
The distance of that object is 6197 light-years, and the thing that makes us believe that there is a black hole is that the target is a powerful X-ray transmitter. But we believe that is the black hole, and the only certain black hole, what we can surely say is a black hole or object what escaping velocity is higher than the speed of light is the center of the Milky Way.
So the distance to the center of our galaxy is 27000 (+-10000) light-years. And if we would send the laser ray to each of the targets, we can see what happens after 6197 or 27000 years, if we would use spacecraft, which travels by speed of light. Otherwise, we should wait two times longer if we want to get an answer, what happens when laser ray impacts to the black hole.
And the time to wait 123494 or 54000 years is a little bit long time. So what would we see, if we can follow the laser ray journey to that black hole? Maybe the laser ray would just disappear or it can turn back to us. But it cannot move faster than other photons. This makes theories so fascinating. Until they are proven wrong or right everything is possible.
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