Great Country Academician

First, if you have money, you can be willful!

For the CRHPC organization, the consumption of electricity is almost meaningless and has never been a factor in our considerations for arranging collision experiments.

Standing next to Xu Chuan, Arthur MacDonald twitched his lips when he heard this.

He couldn't help but give a five-star review to this β-pretender.

The funds and energy consumption that can be used to conduct multiple relatively low-energy collision experiments were thrown into high-energy collision experiments without blinking an eye.

And the purpose is only to obtain clearer collision experiment data.

But you have to know that for high-energy physics experiments, confidence, that is, the degree to which the physical phenomenon shows that the true value of this parameter has a certain probability of falling around the measurement result, is the real core key.

Although clearer collision experiment data can also help improve confidence, the best way to improve confidence is to increase the number of collisions and collect enough data.

In other words, high-energy collision experiments also require multiple collisions to collect enough information data.

This means that CRHPC will invest several times, or even dozens of times, more money and energy in this collision experiment.

Thinking of this, Arthur McDonald couldn't help but sigh in his heart, and couldn't help but sigh.

Really rich, just willful!

In the main control room, the collision experiment that is about to begin is almost ready.

Coming from the other side, Professor Wei Zheng, who is responsible for the preliminary preparations and maintenance of the CRHPC collider, came over and looked at Xu Chuan seriously.

"Report to Academician Xu, all units are ready and can start the collision experiment at any time!"

Xu Chuan nodded, looked up at the time on the main monitoring screen, 9:28, about two minutes away from the set time.

But the impact is not big, and the experiment can start now.

Taking a deep breath, he pressed the headset and gave the order calmly.

"Attention all units and teams, the first 35Tev inert neutrino and dark matter verification collision experiment is now underway!"

"Received!"

"Received!"

"."

The collision command was quickly transmitted to the ears of the teams that had already prepared.

The fusion reactor power station built specifically for the collider continuously converts energy from deuterium-tritium plasma and transmits it to a depth of 100 meters underground.

The long and narrow circular pipe made of superconducting materials is brewing an extremely large magnetic field.

It is a powerful and terrifying magnetic field far exceeding that of the earth and even the sun. Around it, even the neutrinos, which have very weak interactions with other substances and are known as the "invisible man" and "ghost particle" in the universe, are disturbed.

This is also one of the reasons why the Large Intense Particle Collider was built 100 meters underground.

If the scientific research equipment that can form such a terrifying magnetic field is built on the ground, it may cause serious interference to the surrounding information equipment when it is running.

Of course, in addition to this, it will not be accidentally entered by ordinary people or destroyed by malicious elements when built underground.

Haven't you seen that every year when CERN conducts collision experiments, it will cause protests and sabotage from various extreme environmental protection organizations or other organizations.

Many ignorant and fearless people will even sneak into CERN and even enter the collider pipeline, forcing the LHC collider to stop operating several times.

This is the result of the LHC large particle collider being buried hundreds of meters underground. If it is built on the ground, I am afraid that CERN will never have peace.

Of course, for China, it is almost impossible for someone to sneak into the underground to destroy the collider pipeline and force the collider to stop operating.

The reason why they chose to build the CRHPC circular super particle collider at a depth of nearly 200 meters underground is mainly to better conduct scientific research experiments.

After all, the 200-meter-thick rock and soil can shield external interference and cosmic radiation and other external factors that may affect the operation and sensitivity of the collider to the greatest extent.

When the magnetic field intensity gathered in the superconducting channel reaches the predetermined standard, when the final time point comes, two huge and tiny proton beams are released from the linear acceleration orbiter.

Along the predetermined orbit, each proton beam containing billions of protons runs wildly along the path planned for them by the magnetic field in the superconducting channel.

When the energy level reaches 35Tev, at the intersection of the detector, the silent proton beams collide like thousands of troops.

There is no loud sound, no brilliant sparks, only the proton collision with a probability of one in a billion.

In the microscopic world, the billions of proton beams are like two merging galaxies. Although the number is huge, it seems extremely empty compared to their own volume.

Only some lucky ones with a probability of one in ten thousand or even lower, collide with each other under the distortion of the magnetic field, or collide with other microscopic particles that originally exist in the vacuum of the collider.

Under the blessing of enormous energy, the protons were like bullets that suffered a violent impact and shattered into microscopic particles smaller than protons.

In the fleeting time, even in nanoseconds that cannot be calculated by all the most sophisticated luxury mechanical watches in the world, these particles are either broken or merged into new particles, and release their own unique signal fluctuations.

This is Xu Chuan, and it is also what the CRHPC organization and even the whole world are looking forward to!

The extremely precise and sensitive superconducting ring field detector, kinetic energy trajectory tracking detector, and dark matter detector. At this moment, all the signal fluctuations were recorded and quickly transmitted back to the computing center.

Here, the supercomputing center, which is also built exclusively for the CRHPC circular collider, can quickly pre-process these raw data with the help of countless staff, programmers and various mathematical models.

Compared with the CERN organization, this is a unique advantage of CRHPC.

After all, CERN needs to share the processing of collision experiment data through various cloud computing resources. The members of the European Union and CERN do not have so much funds. After spending billions of dollars to complete the construction of the LHC large particle collider, they spent hundreds of millions to build a supporting supercomputing center specifically for it.

In order to save costs, CERN is eager to let private cloud computing resources help process experimental data.

CRHPC is completely different. At Xu Chuan's request, the supporting supercomputing center cost more than 2 billion to complete, and it was RMB after appreciation.

Of course, CRHPC also has a cloud computing resource center.

Not only to save money, sometimes when the supercomputing center is unable to process huge amounts of data in a short period of time, the experimental data will be uploaded to cloud computing resources for split processing.

This approach allows the CRHPC organization to complete the analysis and processing of collision experimental data at the fastest speed.

The reason why several important coupling constants predicted in the strong electric unification theory can be completed in just two years is not only due to the powerful performance of the collider, but also the credit of this computing processing center.

Sparks and fragments are lasing, energy and matter are manifested, and the detector deployed on the pipeline completely records the light generated by the first round of 35Tev collision experiments.

The experimental data that has been pre-processed in the supercomputer is presented on the monitoring screen and caught Xu Chuan's eyes.

This is the first line of receiving particle collider collision data. Any data captured by the detector will be presented on the display screen here.

For a physicist, especially a physicist who studies cutting-edge theories, this is definitely the most wonderful picture in the world.

Although he cannot see it with his naked eyes, the rough energy spectrum images and data channels show him what is happening in the microscopic world.

For Xu Chuan, this is probably something he will never see enough in his lifetime.

The first round of 35Tev inert neutrino and dark matter verification collision experiments officially ended, but the two hundred meters deep circular super particle collider under his feet is still running.

And it is still supplying experiments in higher energy levels.

After all, for today's experiment, it is far from completing its mission.

The scientific researchers and related engineers stationed at various positions began to quickly adjust various experimental parameters. The fusion reactor several kilometers away also increased its output power, continuously inputting huge amounts of electricity into the superconducting pipes of the collider.

The magnetic field, which is strong enough to affect the movement of neutrinos, is further improved, heading towards the threshold of 50Tev.

For Xu Chuan, the entire physics community, and even the whole world, this is a collision experiment that determines fate.

If the theory of void field and dark matter is correct, then in the collision experiment at the energy level of 50Tev, they can find higher energy level surge phenomena than those in the collision experiments at the energy levels of 17Tev and 35Tev, and they can also find larger dark matter particles than those observed at the energy level of 17Tev.

This will verify whether Xu Chuan's theory is correct, whether dark matter particles have the ability to transform into each other, and the first substance in human history that exceeds the standard model.

In the main monitoring room, there was not too long to wait.

When the energy level in the superconducting channel quickly increased to the 50Tev level, the second round of collision experiments began.

The two proton beams continued to move towards the limit value of the speed of light in the nearly 100-kilometer superconducting channel, and finally converged together.

The particle collision with a probability of one in a billion flashes a spark of truth on the detector.

It is the cornerstone of human civilization's progress and the eyes of the physics community to further understand the mysterious universe.

In the main monitoring room, staring at the customized large screen that has been planned to be divided into dozens of different screens, Xu Chuan held his breath and waited for the arrival of experimental data.

When the first round of data from the 50Tev energy level collision experiment was pre-processed by the supercomputing center and projected onto the screen, a bright light flashed in his eyes.

Although he did not participate in the previous 17Tev and 35Tev energy level collision experiments to explore inert neutrinos, he has carefully read the experimental data of those abnormal energy level surge phenomena.

Including the original data corresponding to those energy level surge phenomena, he has carefully read them.

Perhaps it was very difficult for him to directly judge the experimental phenomena existing in these rough raw data on the spot.

After all, it is extremely difficult to accurately analyze and find a new experimental phenomenon from the vast sea of ​​raw data. What is needed is not a smart brain, but powerful supercomputing and computing resources.

But if we only compare the raw data generated by proton collision experiments under the same conditions at different energy levels, it may still be a very difficult thing for others.

But for Xu Chuan, with his two lifetime experience and keen senses on the front line of high-energy physics, this is not a particularly difficult thing.

The collision experiment at the 50 Tev energy level has revealed to him a corner of the mysterious properties of dark matter particles in chaos.

At the same time, Edward Witten, who was standing next to Xu Chuan and staring closely at the surveillance screen, also had a hint of disbelief in his eyes and muttered to himself.

"God, it is actually possible to have inflation at multiple different energy levels."

Perhaps he was not as sure as Xu Chuan, but as he was also proficient in mathematics and particle physics research, it was obvious that he also noticed something unusual in these rough preprocessed data.

Although this does not help him be 100% sure, after all, even if there are indeed dark matter particles of different masses, the answer will only be given after detailed analysis of experimental data and an accurate Dalitz diagram.

But there is no doubt that the void field and dark matter theory proposed by his student is more likely to be on the right path.

At the same time, on the other side, Professor Gerner Hamilton from the Germanic Planck High Energy Physics Laboratory also frowned and looked thoughtfully at the raw data that had only been preprocessed, with a somewhat complicated expression on his face.

As the first scholar to discover the phenomenon of abnormal energy level explosion during the detection of dark matter, Xu Chuan and Witten may not be as familiar with these experimental data as he is.

Although his mathematical physics ability is not as good as the previous two, he cannot accurately identify new phenomena from these raw data.

But when he looked at the experimental data, an idea couldn't help but pop up in his mind.

Perhaps, their physics may really be entering a new era.