“A new experiment offers intriguing clues about one of physics’ deepest questions: the origin of mass. By probing an exotic, short-lived nuclear state involving a heavy meson, researchers uncovered evidence that particle properties may shift inside dense nuclear matter. Credit: Stock” (ScitechDaily, Where Does Mass Come From? Scientists Find Evidence of a New Exotic Nuclear State)
The mass is one of the biggest mysteries in physics. The question of what constitutes mass is a key element in physics. The mass has a straight connection. With gravity. There is a structure that binds quantum fields. Otherwise, it affects all three other fundamental interactions. When the matter binds quantum fields, the quantum field from outside tries to fill that space. And those fields pull particles and wave movement with them. This causes a situation that. Light can travel faster in a gravitational field than outside that field. This requires that the photon travels.
To the gravitational center. The speed of light is relative. It’s relative to the speed at which its environment travels. So if the speed of the quantum field is 20 % of the speed of light, that means the photon travels 20 % faster if we compare its speed with the speed of a photon outside the quantum field. Because a photon is inside a quantum field, it travels in a gravitational field. It doesn’t break the laws of physics. When an object falls into a black hole through the event horizon. Its speed. Comparing with the environment is zero.
When a photon or any other particle escapes from the gravitational field, its speed decreases. The impacting quantum field forms an electromagnetic shadow behind it. So the gravity center pulls energy out of the particle. So when a particle travels to the gravitational center. It will pull energy inside it. But when it escapes from that field, it must deliver as much energy as it got.
But then. The particle tries to escape from that field. The particle must release or transfer as much energy to the field around it. As the field transitioned into it. When the speed of the field and the particle is precisely the same. The field cannot transfer energy into a particle. That is one of the reasons why nothing can escape from a black hole. The energy transition between particle and field ends. When they travel at the same speed.
Impression of a photon rocket that could transport people to stars somewhere in the distant future.
What if the gravitational center suddenly disappears? The particle will not need to deliver the energy that it got when it fell to the gravitational center.
When a particle tries to escape from a black hole, the quantum field creates a shockwave ahead of it. If a particle tries to stop and turn around, the wave forms at the front of it. Another thing is the quantum shadow behind it. And that shadow pulls energy out of it. When the field travels .To the gravity center. With a speed 20% of the speed of light, the impact speed of the static particle and field is 20% of the speed of light.
This means that the photon’s speed is 20 % lower if we compare the escaping photon’s speed with the speed of a photon that travels outside the gravity field. The photon can travel faster than other photons when it travels to a gravitational center. So, the photon that escapes from a black hole needs to use as much energy as it had when it traveled to the gravitational center.
This paradox causes an interesting idea about crossing the speed of light. The speed of light is the cosmic speed limit. But if the fields travel to the gravitational center. With a speed. That is about 30% of the speed of light. And the speed of the hypothetical craft. It is about 75-80% of the speed of light; there is a possibility. The craft detonates the gravitational center. This means that the gravitational effect disappears. And that thing removes the need to deliver energy for escaping the gravity center.
The explosion forms the impacting field. That speed is near the speed of light. And that causes a situation where the impact speed with craft and field is higher than the speed of light.
Gravitation pulls objects. Like a river pulls woods and other things with it. There is a theory. That. There is a tornado-shaped structure or a small black hole in the middle of each particle. This means that particles are the halos of the quantum-sized black holes. The thing that makes those theories interesting is that reseachers in Brookhaven National Laboratories created quarks by colliding composite particles called hyperons.
Those impacts formed quark-antiquark pairs. And the Brookhaven staff. Can detect those particle-antiparticle pairs from debris. Those collisions formed. The thing is that hyperons form quark-antiquark pairs when. It decays into two particles. The spin of those particles is opposite. And that makes them particle-antiparticle pairs. The effect that forms matter straight from energy. Or wave movement called the Schwinger effect.
Colliding quantum fields form the whirl that starts to condense. That whirl forms in the borders of those impacting fields. The question is, what stabilizes those whirls or balls? The thing that stabilizes them is the thing that gives mass to matter. The matter is a condensed quantum field. But what condenses it? And what binds quantum fields in matter?
Quantum fields are the common name for the four fundamental interactions. The time dilation and its connection. Mass and gravitation are well-known. The reason for that is that gravitation condenses quantum fields. And that thing slows the particle’s evaporation. Condensed quantum fields are the result, not the reason, for something that binds those fields. This means that gravitation interacts similarly with all other fundamental interactions. And that makes mass and gravitation interesting things.
https://interestingengineering.com/science/scientists-observe-particles-emerging-from-nothing
https://scitechdaily.com/where-does-mass-come-from-scientists-find-evidence-of-a-new-exotic-nuclear-state/
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