From University Lecturer to Chief Academician

Among the four conventional forces, gravity is ubiquitous.

Particle-related physics research rarely talks about gravity, simply because the role of gravity is so insignificant that it can be ignored in most cases.

The original definition of annihilation force is the microscopic manifestation of gravity.

So, to some extent, you can think of gravity as the force of annihilation, or conversely, think of the annihilation force as the force of gravity.

S-wave, is the definition of radiation detected by a directional gravitational field.

There is a great correlation between S waves and annihilation force, so directional S waves are equivalent to creating a directional gravitational field.

Directional strong S waves create a directional strong annihilation force field, and the strong annihilation force field has a clear effect on microscopic particles.

For example, it can cause atoms to undergo electron shell transitions, and it can also cause materials to produce magnetization effects.

The directional strong annihilation force field has a great impact on particles.

In a conventional annihilation force field environment, the gravitational field has only external manifestations, and its direct impact is the force on the object. When matter is in an antigravity field, it only affects the force, such as being in a field of force. Areas with different environments have minimal impact on the particle level.

A strong annihilation force field can directly affect the particle level, so a directional strong annihilation force field will have a great impact on particles. It will cause the outer electrons of the atom to be squeezed in one direction, which will quickly cause the electron layer of the atom to collapse. Being stripped off, the energy floating inside and outside the atom will be annihilated.

Under this basis, a special singularity appears, which continuously emits strong reverse S-waves in all directions. The particles inside the material will be affected by the strong annihilation force field in one direction, and the atoms themselves will be greatly damaged.

The electron layer is stripped away, which is just a regular effect.

The atomic nucleus will also be greatly affected, because the protons and neutrons inside the nucleus will also be affected by the unilateral annihilation force field. When the intensity reaches a certain level, the electromagnetic properties of the protons can be stripped away, and the protons will become neutrons. This will cause the nucleus to disintegrate directly.

This is nothing new.

In fact, the concept of ‘neutron star’ has long been known in astrophysics, and some celestial bodies have even been defined as ‘neutron star’.

In other words, under a sufficiently strong gravitational environment, the atomic nucleus cannot remain stable, and the protons will be stripped of their electromagnetic properties and become neutrons.

A sufficiently large conventional gravity can disintegrate the atomic nucleus. Coupled with the effect of a strong annihilation force field pointing toward the singularity, the situation will develop even more extreme.

A high-intensity directional strong annihilation force field can greatly weaken the repulsion between particles.

Specifically, it can be understood that the original repulsion between particles is in the opposite direction. After being affected by the unilateral directional annihilation force, the mutual repulsion will produce an inclination angle.

The stronger the annihilation force, the larger the inclination angle will be.

Then, the distance between the particles will be closer and they will fit very closely.

What Paul Phil-Jones said about 'particle sticking' is not accurate, because when particles stick together, the repulsive force between them becomes infinite.

However, describing it as "the distance between particles is infinitely close" is correct to a certain extent.

When particles can be infinitely close, the mass around the singularity will be very concentrated. The specific extent to which it can be concentrated can be calculated mathematically. It may not be possible to calculate accurate results, but the approximate magnitude can still be roughly estimated.

In that environment, a special area with highly concentrated mass will definitely form around the singularity.

This creates a literal black hole.

Paul Phil-Jones, Chen Mengmeng and others couldn't help but swallow their saliva as they thought about it.

They cannot create ultra-high-magnification strong S-waves, nor can they create a singularity that releases reverse S-waves.

However, their research is to create directional strong S waves.

To a certain extent, what they are studying is the technology that can create black holes. What is missing is direction control and extreme intensity.

Everyone started to worry about the experiment.

"We are just creating single-power directional strong S-waves, and there is no danger. Of course, you still have to be careful during the experiment."

"It's best not to participate in the experiment at close range..."

Wang Hao comforted the people in the theory group. He also felt very scared, but after thinking about it carefully, he didn't care.

There is danger in the laboratory, and he can tell it in advance.

This is the greatest safety guarantee.

Only by ensuring safety can we conduct experimental research with peace of mind and not stop because of danger.

They continued to study the theory.

The main content of the research is also focused on issues such as 'electromagnetic stripping of atoms' and 'electromagnetic stripping of protons'.

"In an extreme environment where a singularity exists, what does 'electromagnetic stripping' mean? It shouldn't be annihilated, right?"

They first ruled out annihilating mass.

Even annihilating electrons is not that easy. Annihilation mass points only exist in the environment of "extremely strong annihilation force fields that can carry energy up to the upper limit".

In an environment where there is a singularity that releases an ultra-high magnification directional annihilation force field, if you want to "reach the upper limit of carrying energy", the energy required can even be described as endless. A super-large star can concentrate all its energy into one point. The singularity position must be able to carry energy up to the upper limit.

This can be roughly calculated mathematically, and then a conclusion can be drawn by comparing the numerical magnitudes.

The point put forward by Chen Mengmeng is very interesting, "If a singularity creates a black hole, the electrons and protons in the absorbed material particles will be deprived of their electromagnetic properties."

"These special substances or special energies with strong electromagnetic properties are likely to exist in the outer layers of black holes."

"The strong electromagnetic force in the outer layer will affect the material inside."

"We can assume that the strong electromagnetic force in the outer layer will continue to increase, and the impact on the interior will become larger and larger..."

"When it reaches a certain limit point, a special reaction may occur with the center, forming a huge electromagnetic storm, and ejecting a storm of ultra-high-energy particles from the surface to the interior..."

Among Chen Mengmeng's views, only "electromagnetic matter or energy is thrown into the outer layer of the black hole" has certain foundation support.

The follow-up is all based on the imagination of basic support.

But her point of view is very interesting because it explains a special phenomenon of black holes-

Black hole erupts!

This is an unsolved problem in astrophysics.

Chen Mengmeng is using the existing basis to explain the phenomenon of black hole eruption. She proposed the idea that when electromagnetic matter or energy in the outer layer accumulates to a certain extent, an 'electromagnetic storm' will occur.

Everyone else's eyes lit up when they heard this.

Based on this point of view, they can conduct a series of analyzes to analyze the black hole eruption phenomenon from the perspective of annihilation theory.

…

For the next period of time, the theory team has been using the annihilation theory to analyze issues related to black holes.

There are two main points.

One point is that the central singularity releases special strong S waves and has an effect on particles.

The second point is that electromagnetic stripping will be repelled to the outer layer of the black hole. When accumulated to a certain extent, an electromagnetic storm will be generated, which will cause the material inside the black hole to erupt.

Although there are only two problems, the theory involved is too complicated and involves a lot of mathematical problems. Just the calculation is a headache.

The study lasted two weeks.

Wang Haodu spends more than four hours a day participating in theoretical research work. He is also very interested in the construction of black hole-related theories.

The physical environment inside a black hole is extremely complex and cannot be explained by the singularity and the electromagnetic outer layer. It must also include many other physical phenomena, but it is already remarkable to be able to achieve this.

Black holes have always been the most mysterious objects in the universe.

Many phenomena observed outside black holes violate conventional astrophysical laws.

Research on the internal physical conditions of black holes are just conjectures based on thin air, without any theoretical basis, and even some related contents are contrary to common sense of physics.

So far, annihilation theory has not touched the field of black holes.

Previous research related to the annihilation theory, such as "The Theory of Cosmic Inflation", only talked about black holes as a concept and definition.

In "The Theory of Cosmic Inflation", large black holes are defined as 'possibly existing forever'.

If the expansion and contraction of the universe are defined as a cosmic cycle, then super-large black holes may have experienced countless cosmic cycles.

This is the explanation of the "Inflation Theory of the Universe".

Now we have analyzed two physical phenomena and laws within the black hole, which is equivalent to directly analyzing the physics of the black hole in detail.

After completing the relevant research, Wang Hao personally participated in the compilation of the content. The mathematics content alone is about 50 pages, and also includes more than 20 pages of other related content.

A total of 70 pages of paper were submitted to "Annihilation Physics and Theory", and the title was "Annihilation Physics-Black Hole Theory".

It is said to be a submission, but in fact, there is no need to review it at all.

After several years of development, "Annihilation Physics and Theory" has become one of the most famous physics magazines in the world.

In the latest academic journal rankings, "Annihilation Physics and Theory" ranks third in the impact factor of international physics journals. In the fields of annihilation physics and superconducting physics alone, it ranks first, and its influence is far-reaching. Well above second place, it's a whole new level alone.

The review of "Annihilation Physics and Theory" is also very rigorous. Generally, paper submissions have to go through four reviews, and the publication cycle takes more than four months on average.

In fields related to annihilation physics, having a paper published in "Annihilation Physics and Theory" can be described as an 'honor'.

Many scholars and institutions engaged in annihilation physics research hope to publish their papers in "Annihilation Physics and Theory", which will have greater influence and be recognized by international physics.

Of course, there are exceptions to the rigor of review.

Wang Hao is an exception.

All research papers related to Wang Hao do not need to be reviewed at all and can be published directly.

This is common in international academic circles.

Other international academic magazines do not require reviewers for Wang Hao. Of course, Wang Hao rarely submits articles to other academic magazines.

…

A week later, "Annihilation Physics and Theory" released a new issue. Only four papers were released in the new issue.

"Annihilation Physics-Black Hole Theory" occupies two-thirds of the page.

Many scholars saw the new issue of "Annihilation Physics and Theory" and immediately noticed "Annihilation Physics - Black Hole Theory". The authors of the paper are really famous, including Wang Hao, Paul Phil-Jones, Chen Mengmeng, Helen, wait, it seems that it was completed by Wang Hao's research team.

Every time Wang Hao publishes a paper, it will be a very significant achievement.

The last time I published content related to gravitational fields and S waves.

Before the publication of the paper, the outside world did not even know that directional gravitational fields existed, nor did they know what S waves were, and the related technology was unthinkable.

Now that the results have been published again, many scholars and institutions immediately read the paper. After reading the introduction, they felt a little disappointed.

Because the content of the paper is about black holes.

Black hole…

The relevant theoretical content is difficult to say.

Even if all the research is correct, it only exists in the theoretical category. In addition, similar research cannot be verified at all.

Many scholars discussed, "It is a brand new theory to explore the issue of black holes."

"It is a study based on the annihilation theory, which means continuing to improve the annihilation theory, but it also mentions the concept of super S wave."

"Super S wave... is defined as a directional strong annihilation force field?"

"Directed strong annihilation force field? It's probably just a theory, it's impossible to create..."

“It feels like it’s something from the imagination.”

"Although there is no detailed verification yet, the mathematical structure they completed is very good and superb."

"Of course, the researchers are Wang Hao and Paul... both are top theoretical physicists!"

"..."

Many people have noticed the two most critical points.

The so-called statement that "electromagnetic matter or energy in the outer layer causes electromagnetic storms" was just a look at it and did not cause much discussion. After all, only top scholars can understand the paper.

In top academic circles, it is nothing to understand black hole eruptions as electromagnetic explosions.

That was also a hypothesis that existed in astrophysics.

Singularity is very different.

The concept of singularity, many people's first impression is the Big Bang. The Big Bang means that a big explosion occurred at a singularity, and a large amount of the original matter of the universe was created, and then the universe itself was gradually formed.

The current description of a black hole is that there is a singularity in the center, and even the starting point is described in great detail——

Release ultra-high intensity reverse strong S wave!

This concept is very novel since it was first proposed, and has aroused widespread discussion among the top physics circles. "Creating strong directional S waves is equivalent to creating a similar environment inside a black hole?"

"If we master the technology of producing directional strong S waves, can we create a black hole?"

"That sounds scary."

"It should be just a theory. Directional strong S-waves should only be an imaginary technology..."