Effort to understand the path of gravity's impact on quantum levels, physicists have recently developed a new model with an interesting meaning: tiny black holes can exist throughout where, every element can be made up of many different types of black holes.
Scientists include Donal Coyne of the University of California Santa Cruz (now deceased) and DC Cheng of the Almaden Research Center near San Jose very cautiously with this view. But they think it's worth studying with the Large Hadron Collider (LHC) and other high-energy physics experiments. Cruz and Cheng presented their views in an online publication.
According to physicists, gravity is considered to be a tremendous resource, which affects smaller levels that do not seem to exist. However, scientists wrote: 'It is often thought that it is close to the Planck level, gravity somehow asserts itself and has relative strength compared to other resources in nature, it is similar to as a product of a great unified picture '. Coyne and Cheng approached small-scale gravity by conducting a new black hole evaporation model. When black holes lose energy, they gradually evaporate, narrowing the size to quantum - then they are probably equivalent to basic matter particles.
This new model suggests that ' gravity is really strong compared to other resources, but we have not yet conducted trials to find places where it exists. But instead of opening new directions, we look elsewhere. An obvious place where scientists have not yet tested is to find gravity as the horizon of black lakes where temperatures are sufficient for quantum gravity to be useful. We speculate that at this level, the spatial structure of the horizon lines may be too complex compared to what is predicted from general relativity. They may need a bit of freedom to estimate a particular state, they may also cause information to be lost. More importantly, if gravity exists in the horizon and it is really strong, but we have not found any evidence of it at larger scales, then the horizon is complicated. essentially shields'. The false protective horizon is an unusual speculation, which holds that gravity is a very powerful but substantially hidden force.
By studying quantum gravity at black hole horizons, the new model shows that black hole evaporation seems to be the same for basic particle decay. (Photo: Coyne and Cheng)
Coyne and Cheng's article, titled "shielded strong gravity scenario" (SSGS), is based on the principles of high-temperature physics and thermodynamics that can model black holes at all levels, but the The difference in this method indicates that the black holes are only below the Planck or Planck level , and the research model stops understanding the extraordinary thermodynamics of the black holes. Dictionary, instead creating a state that is more and more similar to an object that obeys traditional thermal physics, for example, in the new model, the evaporation of black holes is not limited to the infinity of objects. reason, it carries the traditional thermodynamic characteristics after undergoing a marked phase change.
In other words, the model predicts that any state detected at masses below the Planck level will behave normally, and will become very similar to basic matter particles. 'Perhaps the most reassuring conclusion we have obtained is that the dynamic solution in both models forces states below Planck to adhere to the Heisenberg principle, thus allowing them to act like objects. Normal substances, ' scientists write.
When they discovered how small black holes work, they find that the quantization of the universe at this level means that mini black holes can carry many different levels of energy and with numbers. large amounts. Scientists predict that mino black holes can be so popular, so common that every molecule can be different forms of black holes at different energy levels.
Coyne and Cheng wrote: 'At first glance the prospect that the SSGS study suggests seems strange but not so. That is exactly what one would expect if a black household is evaporating leaving the remnants consistent with quantum mechanics. It can be assumed that black holes gently transform into a rather large object and may also be an unstable basic matter particle, when it continues to evaporate (decompose) to return to more common static state. This may bring a new perspective on the evaporation process of large black holes, which do not seem to have any difference in the principle of relative decomposition of basic matter particles'.
One of the implications of this model might be dark energy and dark matter - apparently acting as a repulsive force - in fact that may be surrounded by a group of gravitational black holes at the molecular level. basic. Such capabilities are however difficult to verify. Although it may be possible to experiment with LHCs in the future, it may be possible to conduct samples for black hole areas. Scientists emphasize that this is what high-energy physics is doing all the time with different energy levels. We may not be able to remove black holes from basic matter elements if there is really no fundamental difference between them.