The internal acceptance report of the 125Tev energy level collision experiment will soon enter the questioning session.

Regarding the last result of this inert neutrino and dark matter particle detection experiment, there are many people raising their hands to ask questions like crucian carp.

This is the first time that the physics community has verified particles beyond the standard model, and it is also the first time that human civilization has explored the mysterious field of dark matter. No one will give up leaving his name and glory on this historical monument.

Starting from the 35Tev energy level to the 100Tev energy level collision experiment has passed the acceptance report meeting and has their own belongings. 125Tev is the last one, and the one who has no master yet.

And for Nanda and Magical City Jiaotong University, it is even more impossible to give up this hard-won opportunity easily.

On the report stand, Professor Zhao Hu answered every question calmly and calmly, striving to be perfect.

Time passed little by little, and the questioning session lasted from 9:40 in the morning to 10:30. The battle that lasted nearly an hour later stopped.

In the audience, the acceptance team of the front CRHPC agency exchanged opinions with each other. After confirming that there was no problem, it announced that the acceptance report of the 125Tev energy level collision experiment jointly submitted by Nanjing University and Magic City Jiaotong University was successfully passed.

When the experimental data of the sentence "125Tev energy level inert neutrino colliding experiment with dark matter" was officially passed the acceptance of the CRHPC organization, the applause in the venue rang like thunder.

With applause, Xu Chuan took to the stage to replace Professor Zhao Hu, who was the Jiaotong University of Magic City.

After once again expressing his respect and gratitude to the two universities and related research institutions that made this contribution, his eyes scanned the thousands of listeners in the venue, and a hint of aroused his lips.

Facing these two pairs of expectations or solemn sights, he spoke slowly in a clear voice.

“Seven years ago, when I was studying at Princeton University, I went to the CERN institution for further study.”

"In a collision experiment of 13Tev energy level, I discovered some abnormal phenomena and finally confirmed that in the vast universe, in the microscopic world, there is still a particle that we cannot see."

Without extra words, Xu Chuan went straight to the topic and continued.

"This is a particle in the 120um (rφ direction) beam z observation data of the anti-helium-3 nucleus of the internal trace system. It may be the legendary dark matter, or it may be some kind of particle that we have not explored before."

"But due to the limitations of the detection equipment and technology used at the time, we can only see part of the information of this particle, but we cannot see its full picture."

"And now, in the CRHPC mechanism, we have a more powerful particle collider. Starting from the 13Tev energy level experiment, to 17Tev, to 35Tev, to the final 125Tev..."

"Step exploration and step-by-step experiments allow us to finally master the entire picture of this mysterious particle, and we also gain more information about other particles similar to it."

At this point, Xu Chuan paused slightly, glanced at the audience, looked at the silent lecture hall, and looked at the countless people holding their heads waiting for the answers, he smiled and continued in a relieved tone.

"I am honored to be here today, representing CRHPC and the theoretical physics community, to announce our latest research results to everyone."

Hearing Xu Chuan's words, the entire venue became noisy, and the rustling discussion sounded almost everywhere. Everyone's faces showed a look of surprise and surprise, but there was a look of excitement and expectation in their eyes.

The acceptance report of the 125Tev energy level collision experiment will not be the end of the detection experiment of inert neutrinos and dark matter particles. Although today's acceptance report will make everyone look forward to it, what everyone is more looking forward to is when the scholar standing on the stage will be able to carry out a complete report.

After all, the former is just a phased result, while the latter is the real breakthrough.

However, even so, most people probably never thought that the person in front of them could carry out this report at today's acceptance report meeting.

After all, even if you organize the experimental data of these different energy levels, it will take time.

What's more, when facing particles such as inert neutrinos and dark matter particles that exceed the standard model?

No matter how long it takes to repeatedly verify them is a matter of no exaggeration.

His eyes glanced around the audience, and Xu Chuan continued with a pleasant smile on his face.

"Seven years ago, I asked everyone a question at a phased report meeting of lazy neutrinos, that is, what is the biggest puzzle that the human science community has encountered so far when facing the vast universe?"

"And today, I can stand here to answer this answer!"

As he said that, he turned to face the blackboard placed on the report table, picked up the marker from the pen basket, and wrote three big words on it.

【Dark matter!】

"This is a kind of 'matter' that exists in the universe and is difficult to directly observe and see with current human technological means. It is the main component of the matter in the universe and constitutes a very small part of the star body and most of the invisible structures of the visible celestial bodies."

"For example, supermassive black holes in the center of some galaxies, such as dark matter stars, some quasars, etc."

"I am not the first to propose this concept. As early as 1922, Professor Kaptan proposed that invisible matter that may exist around the astral bodies affects their movement and structure.

"In the following century, countless scholars in physics tried to find this invisible matter that affected the structure of the universe and the movement of galaxies."

"For example, in 1933, astrophysicist Zwicki used spectral redshift to measure the movement speed of each galaxy in the posterior galaxy cluster relative to the galaxy cluster."

"Using the positional force theorem, he found that the velocity diffusivity of galaxies in galaxies clusters is too high, and the gravity generated by the mass of visible galaxies in galaxies cannot be bound to the clusters. Therefore, there should be a large amount of dark matter in the cluster, and its mass is at least a hundred times that of visible galaxies."

"Or in 1959, Professor Kane and Watt studied the relative motion between the Andromeda Nebula and the Milky Way, which attracted each other. Through the speed and distance between them, we infer that the dark matter in the galaxy clusters in the Milky Way where we humans live is about ten times larger than visible matter, etc."

"Although there is so much evidence that there is a kind of matter in the universe that we humans cannot see affecting the movement of the universe and the structure of galaxies, unfortunately, until today, the properties of the particles that make up these invisible matter are still not understood."

"Even if such mysterious particles really exist is an unanswered question."

"After all, we cannot be sure whether there is really a particle in the universe that is stable, uncharged, without strong interactions, and has only weak gravitational and weak interaction properties."

"We can't see it directly through the collider, nor through other devices."

"It is puzzling whether a particle that is invisible and incomprehensible actually exists for any civilization."

"But today, after experiencing countless collision experiments and sacrificing countless particles, we finally found one of these mysterious particles!"

"Inert neutrino!"

After pausing for a moment, Xu Chuan wrote this name on the blackboard and continued:

"According to the division of the Void Field and Dark Matter theory, it is a medium-mass dark matter particle that forms part of our universe and is widely distributed in every piece of time and space."

"Even at this moment, it traveled through all of us like a ghost."

"It does not have strong interaction forces, nor does it have electromagnetic interaction forces. Its properties are highly stable and hardly reacts with ordinary matter. But it will also act with other matter through gravity and certain forces or forms that we have not yet fully explored."

"The most important thing is that it can release a large amount of dark energy while releasing a smaller mass dark matter particle when it breaks the void."

“This is an important reason that drives our universe to continue to expand!”

The incredible voices from the audience gradually spread, and many people wrote a hint of surprise even stronger than before.

The dark matter theory in the Void Field can be said to have seen it all today, but there is no such section reported in it.

Dark matter particles are related to dark energy, and dark energy is released by dark matter particles at the same time.

Although this explanation is indeed logical, it is also in line with the phenomenon that the universe is still expanding or even accelerating from more than one billion years ago to now.

But most of them didn't understand why Xu Chuan made the conclusion so decisive.

After all, for today's physics, although it proves the existence of dark matter particles, it is still a puzzle whether they have many forms and whether they are really related to dark energy.

Noting the expressions on these people's faces, Xu Chuan smiled faintly, turned around and walked towards the blackboard behind him, picked up the marker and wrote on it:

【Ct】

"Ct particles, i.e., inert neutrinos, are my simple names for it. Of course, this is a symbol temporarily set for easy writing. Maybe I will modify it in the future."

"But now this is not the most important thing."

"It is important that by collecting the collision experiment information data from the 13Tev energy level to the 125Tev energy level, it is shown that Ct-indulgent neutrinos exist in the collision experiment of a certain energy level segment."

"Below I will use the collision experimental data from multiple energy-level segments such as 13Tev, 17Tev, 35Tev, 50Tev, etc. to explain how inert neutrinos transform into other dark matter particles of the same energy level and mass level through the void breaking phenomenon, and crack into dark matter particles of smaller mass and smaller energy levels."

"I will write as detailed as possible, but I can't guarantee that everyone present can fully understand my theory."

"After all, this is impossible."

After the words came, Xu Chuan took a deep breath, turned around and looked at the blackboard, raised his right hand and wrote on the blackboard:

"Ct-inert neutrino is a dark matter particle. Before fully understanding its properties, we need to examine whether its time scale is stable at the age of the universe. The pattern of Ct-inert neutrino fission into smaller mass particles through the void breaking effect, and the corresponding lifetime can be written as..."

"Ct=2.88*102?{Ms/0.1KeV}ˉ?·{θ2/10ˉ?}ˉ1KeV..."

"Where Ms and θ are the mass of inert neutrinos and their mixing angle with smaller dark matter particles formed by fission, respectively."

"From this we can see that the lifetime of the inert neutrino in Ct is much greater than the age of the universe, but this does not conform to my prediction in the Void Field and Dark Matter theory."

"So I introduced the void breaking effect in this process, and I wrote it as the X effect, which occurs in dark matter particles that can be fissioned through high-energy-level environments or can be fissioned. Through this type of effect, large-mass dark matter particles will actively fission, releasing a large amount of dark energy and smaller dark matter particles."

"The expansion effect of the universe indirectly confirms that large-scale dark matter particles are always fission. They release a large amount of dark energy in this process, driving the expansion of our universe."

"From this, we can imagine that in the early universe, large-mass dark matter particles were more and more dense than the clumps or star bodies composed of large-mass dark matter particles."

"It is precisely because they are constantly passing through the void breaking effect that they promote the development of the universe and space-time, constitute our current universe, and are still constantly advancing outward."

"By observing the inert neutrino Ct particles in multiple energy level areas, we can confirm that the fission energy level region of the inert neutrino in the Ct particle is Ct=XCt·13TeV2?|△m2/41|?XCt·17TeV2."

"That is, in the energy level area between 13Tev and 17Tev, inert neutrinos will naturally fissure a smaller mass dark matter particle through the void breaking effect and release a large amount of energy."

"And the formula for calculating the dark energy it releases is..."

......
Chapter completed!