Genius of the Rules-Style System

The research on ‘Z-wave detection technology’ begins with the detection of controllable charged particle beams. The research method relies on a small electron gun to release a Z-wave compressed electron beam in a vacuum environment, and then detect the electrical energy after completing the compression.

The charged particle beam will be constrained by a high magnetic field and will run at a high speed in a fixed arc, eventually hitting the target for detecting electricity.

Particles compressed by Z waves will have a significant increase in activity, which is manifested in a significant increase in electric charge.

The first step is to clarify the charge of the electron beam, perform Z-wave compression and then conduct a test, analyze the difference in charge between the two tests, and then compare the Z-wave compression magnification to obtain certain results.

This is the easiest, controllable, and fruitful way that many people conduct research together in the laboratory.

The principle of the experiment is not complicated. There are two main difficulties. The first is the constraint of the electron beam. To make the electron beam fixed and rotate, a very high-strength magnetic field is required.

This difficulty is very high.

Just like the original magnetic field constraint method for controllable nuclear fusion, achieving that level of constraint requires very large equipment and massive financial support. Obviously, the experimental environment does not allow it.

However, it is only for Z-wave related detection. It does not require perfect constraints on the electron beam. It only needs to ensure that the electron beam does not leave the vacuum range of the experiment within 0.5 seconds or even shorter, that is, it does not hit. The edge of the vacuum environment is fine.

In this way, the difficulty is relatively low.

The design of the experiment mainly revolves around how a high-intensity magnetic field wraps a vacuum environment so that the electron beam is subject to magnetic field forces in all directions, thereby constantly changing its direction.

This work took more than half a month to barely complete.

The second difficulty lies in analyzing the relationship between the increase in electric energy and the space compression ratio.

There is a 'particle compression ratio' between the increase in electric energy and the space compression ratio. What we ultimately want to get is the relationship between the particle compression ratio and the space compression ratio.

Because I have never done any relevant research, I have to start from scratch. The process is to continuously experiment and record data, and in the process there are various mathematical analyses.

The research process is still relatively simple, but everyone is very interested. There are not many opportunities to participate in new research, especially Z-wave detection technology, which is directly linked to the spacecraft project. There is no doubt about its importance. Everyone hopes to have it. Results.

The research on ‘Z-wave detection technology’ took about three months from the start to the end of the first study.

A lot of things happened during this period, such as the completion of the launch of the third and fourth solar-circulating energy-concentrating satellites and their successful operation into their intended orbits.

For example, Yixing Company achieved a breakthrough of manufacturing 50,000 unlimited power vehicles.

For another example, the small spacecraft has finalized its manufacturing plan and entered into rapid manufacturing.

etc.

Zhao Yi and other researchers immersed themselves in experimental research, conducting repeated experiments and constantly recording data.

Three months later, some results were finally achieved. The team found that the electron beam can indeed be used to detect the spatial compression ratio, but there is an upper limit.

In the vacuum environment created in the laboratory, the small electron beam can detect space compression up to about 30 million times.

The magnification of 30 million is already very high, but it is far from Zhao Yi's expectation.

At first, Zhao Yi hoped that by relying on detection technology to instantly detect space compression of more than 100 million times, he could realize rapid space shuttle in and around the solar system.

Obviously.

It is impossible to do this using electron beam detection.

Even in a real space environment, with the support of a high-power nuclear fusion reactor, the theoretical space compression ratio that the electron beam can detect is only 50 million times.

"Fifty million times is a very good figure and can be used directly. However, the magnification rate is still a little worse and does not meet expectations."

At a periodic internal meeting in the laboratory, Zhao Yi said with some regret, "However, our research has proven that the electron beam can only detect up to 50 million times, and it cannot be higher."

What determines the upper limit of the detection magnification is the increase in electric energy. Through continuous experiments, they found that as the compression ratio increases, the increase in electric energy cannot be significantly increased.

Although there is a positive relationship between the two, they are not directly proportional. Instead, they are a parabolic graph with a highest point.

If you continue to increase the compression ratio, the increase in electrical energy will no longer be significant, and will even decrease at a power level.

The increase in electrical energy is still increasing, but the increase is very small.

"This is because when the compression ratio increases to e, it reaches a balance with space squeeze."

"The magnetic field is the situation in which particles resist the squeeze of space. But when it is no longer necessary to increase the magnetic field to resist the pressure of space, the magnetic field will increase very slowly."

"Magnetic fields and electric fields are not separate, they are interrelated."

"So, after the reduction ratio increases to e, the amount of electric energy increase will show a power level decline."

This is also the reason why the highest detection magnification is about 50 million.

When the increased part will show a power level decline, you can only rely on analysis to increase the last part of the decimal point to continue the magnification calculation. The power level decline is very scary, and it will soon require a huge amount of calculations. Definitely increase the value.

Even the computing power of a computer is limited, and the detection space of data compressed by 50 million times is already a 'theoretical state'.

In fact, the experiment concluded that under conventional computing power, it can only detect a maximum of about 43 million times.

This is the end of the first phase of research. The research is relatively successful because they figured out how to detect the magnification of Z-wave compressed space. However, the magnification limit of tens of millions will prevent the space shuttle from being 'too fast'. .

The design standard for the Z-wave generating device of the spacecraft is that it can release and compress a distance of one hundred astronomical units, and at the same time the compression ratio reaches tens of billions, that is, at a speed of 1,500 kilometers per second, it can travel within ten seconds. A distance of up to 15 billion kilometers.

Of course, that's the theoretical maximum speed.

The normal sailing speed of a spacecraft is only on the order of tens of kilometers per second, but the energy level of the Z-wave generating device can support compression rates of tens of billions.

Only a magnification of tens of billions or more can support rapid "light-year" crossings, or even complete travel between galaxies.

If it can only detect 50 million times, it will greatly limit the use of Z-wave generating devices and space shuttle capabilities.

Of course.

A compression factor of 50 million is still very fast in the solar system. If the spacecraft enters the shuttle orbit at a speed of one kilometer per second, it can easily reach Mars in a few seconds.

But this is the progress of research. If you want to detect higher compression ratios, you can only find other methods.

Zhao Yi concluded, “We first summarize, record, and analyze the research at this stage, and then start designing the content for the next stage.”

"In the next stage, we will cooperate with the Institute of High Energy, which has complete neutron beam generation technology."

"The study of neutron beams is what we are going to do."

"Analyzing the changes of the neutron beam at high compression magnification is mainly to analyze the changes of the magnetic field. The detection in this area is relatively complicated. Everyone needs to think about it carefully and make a design."

"Everyone's idea is important, and there may be a relatively simple and direct way."

Zhao Yi made a summary very seriously.

When particles are compressed, they become active, and at the same time they emit a magnetic field to resist higher spatial compression. Therefore, the relationship between changes in the magnetic field emitted by particles and the rate of space compression can also be studied and analyzed.

However, it is not easy to study the changes in the magnetic field of particle beams. The difficulty lies in two aspects. One is that the neutron beam is very difficult to control, and the propagation distance is relatively short.

The other is that the change in the magnetic field emitted by a beam of particles requires very delicate and clever design before it can be detected.

After completing the first phase of research, Zhao Yi found that the difficulty of subsequent research has increased a lot, and it is not easy to continue to achieve results.

The more stable the particle is, the more difficult it is to constrain and detect it.

For example, photons.

Photon beams are the easiest to manufacture and the most stable. At the same time, photon beams are almost impossible to restrain. In a high space compression environment, even if a change in behavior occurs, it is impossible to detect it.

At this time, we understand why we need to build a large particle collider.

If you want to study microscopic particles, you need a large-scale experimental environment. The larger the experimental environment, the easier it is to draw conclusions.

Now in a small laboratory, there is no way to continue a lot of research.

If it were a large planet, and an experimental site for the entire planet could be built and recharged, the gravity of the planet could really be used as the conditions for the experiment to occur, and more secrets of particles could definitely be explored.

If during the experiment, violent space and particle reactions occur, and particles with ultra-high compression ratios are created, it is equivalent to artificially creating a small black hole, and it will be a perfect experiment.

By then, many secrets of microphysics will be unearthed.

Zhao Yi thought carefully and suddenly understood why there are "junk planets" in some science fiction novels.

If you think deeply, you will find that it is completely unreasonable that there is an abandoned planet holding garbage.

No matter how bad the environment of the planet is, it will be very valuable for human survival. How can we treat such a planet as a garbage dump?

Garbage dumps, everywhere.

For example, on some planets without an atmosphere, garbage can be dumped directly there without any disposal problems at all.

Such planets and universes are everywhere.

Now Zhao Yi somewhat understands that the garbage planet is not specialized in collecting garbage. Perhaps it was originally an 'experimental planet'. To support the development of technology for exploring the universe and galaxies, a very large experimental site will definitely be needed.

These planets may have been experimental sites originally, but after the experiments, the planets were irreparably damaged and could no longer support human beings for long-term survival. They could only be abandoned and used to hold garbage.

Zhao Yi thought about it and shook his head with a wry smile.

Now that I think about having a planet as an experimental base, I really can only think about it.

——

Time flies so fast, half a year has passed in the blink of an eye.

The small spacecraft passes through the space channel, and the experimental mission of carrying humans to and from Mars is put on the agenda because the spacecraft has been manufactured.

The next work is to continuously test and proofread the data and make final preparations.

This takes about a month.

The time set by Yixing Company and the space agency is three months later, and the preparation time is relatively sufficient.

Zhao Yi also needs to go to the space agency and work with the responsible team. He must be on the front line to ensure the safety of his work as much as possible.

At this time, a piece of news came and Zhao Yi decided to return to the capital early.

It's He Mingcheng.

He Mingcheng's physical condition has deteriorated extremely and he can no longer support him. The doctor believes that he can survive for a few days at most and may pass away at any time.

After Zhao Yi got the news, he immediately decided to return to the capital early to see Professor He Mingcheng for the last time. He still respected He Mingcheng very much and was very grateful in his heart.

When he was doing mathematical research back then, He Mingcheng still gave a lot of guidance, and he wholeheartedly helped Zhao Yi without asking for anything in return.

In addition, He Mingcheng is an elder worthy of respect. He has been doing research all his life, participated in several large national-level projects, and is also the founder of the domestic fuzzy mathematics discipline.

The most respectable thing about He Mingcheng is the indifference with which he conducts himself.

For example, academician ratings.

With He Mingcheng's fame, achievements, and status, it is not said that he can be directly elected as an academician, but if he really makes the selection seriously, the possibility of being elected as an academician is very high. But he has never done that, and he has never cared. He just concentrates on it. In his own research, he was a true scholar.

Zhao Yi got off the plane at the Capital Airport and went straight to He Mingcheng's home. When he arrived, there were many people at home, and many people were standing downstairs. When they saw Zhao Yi, they immediately let him pass.

"How's it going?" Zhao Yi saw Qian Zhijin and immediately asked about the situation.

Qian Zhijin smiled bitterly and said, "Go and have a look. Teacher He wants to see you and has been reading your name yesterday."

He immediately took a few steps quickly.

As soon as Zhao Yi entered the door, he saw He Mingcheng lying down and shouted softly, "Teacher He!"

"Cough! Cough!"

He Mingcheng coughed several times in a row. He was obviously very weak. He slowly opened his eyes. It seemed that because he couldn't see clearly, he wanted to sit up and take a closer look. The person next to him quickly gave him a hand.

Zhao Yi came closer and said, "Teacher He, it's me, Zhao Yi, I'm here to see you!"

He Mingcheng nodded slightly, straightened up and continued to look forward, not sure if he could see clearly.

After waiting for a long time, he finally spoke, "Zhao——Yi——"

It was difficult for him to pronounce the words, and there seemed to be a smile on his face. It took him a long time to say the complete words, "I, I have been waiting, but you were afraid that you would not be able to see me."

"Well, I'm listening, tell me!" Zhao Yi nodded vigorously and said loudly.

"I have been mediocre and accomplished nothing all my life, but it's worth it, it's worth it, because when I met you, I saw the future."

He Mingcheng became more energetic as he spoke, his speaking speed became smoother, and his eyes became wider, "The future of mathematics, the future of science, the future of the motherland, you represent the future."

"Thank you."

"Xiao Yi, I have always refused to recognize you as a student, because I think that if I can't be your teacher, my level is not enough, my achievements are not enough, not compared to you now, but when you first entered college."

"You are so outstanding that you put me and everyone else to shame."

"However, I still hope to hear you call me teacher, just one sentence."

"OK?"

"After that, just leave, leave, don't come."

After He Mingcheng finished speaking, he looked over carefully.

Zhao Yi nodded vigorously and said loudly, "Teacher! Teacher He!"

"Okay, okay!"

He Mingcheng laughed heartily, and his tone became much higher. He immediately pointed to the door and said, "Let's go, let's go! Let's go! Your work is more important, don't waste your time for me, not even one more minute!" "

"Well, okay, I'm leaving!"

Zhao Yi reluctantly stepped back and took a hard look at the door. Then he stood in the corridor and continued to stand silently, waiting. He knew he didn't have much time left.

It didn't take long for mournful cries to be heard in the room.