Genius of the Rules-Style System

When it comes to studying the issue of ‘whether space extrusion will affect energy beams’, all that can be done for the time being is to think deeply.

Even if we are studying the impact of space squeeze on particle beams, we have to prepare a series of experimental designs and wait for various high-precision instruments to be equipped. It is still uncertain what conclusions can be drawn and how in-depth the research can be. Regarding the matter, the difficulty of researching energy beams is not of the same order of magnitude as that of particle beams, because energy beams are affected by space squeeze, and the impact is very small, so small that it is impossible to detect it in normal experiments. In addition, if you want to control energy beams in a small range, It's almost impossible to do.

The underlying logic of anti-gravity technology is to design the beam to continuously rotate. However, in fact, that is not a real rotation, but a process of continuous annihilation and regeneration of the beam. It is equivalent to forcibly intervening with physics to allow the beam path to rotate.

In short, it is temporarily impossible to study energy beams experimentally.

"That may not be possible at all through experiments. Instead, we need to observe black holes at close range."

In the theory studied by Zhao Yi, it is believed that a black hole is a collection of highly compressed particles, and the black hole itself continuously releases Z waves.

If the beam is affected by the squeeze of space, it will definitely show up next to the black hole.

This kind of observation can only be imagined for the time being.

In the current experimental preparations, it is more practical to study particle beams with mass.

This research is also very important.

Research on Z-wave detection technology will directly affect the safety of space shuttle and directly determine the distance of space shuttle.

Safety is more important than distance.

Technology is slowly improved step by step, and it is impossible to reach the key points in one go.

Zhao Yi hopes that the performance detection of particle beams can first reach the level of determining the 'ten to the eighth power' space compression ratio, which can ensure that the space shuttle distance can exceed dozens of astronomical units, that is, shuttle from the earth in one breath To the Kuiper Belt.

This shuttle distance is not too fast, but it is enough to support the spacecraft as it slowly flies out of the solar system.

——

Research and preparations for Z-wave detection technology are still in progress.

The third-floor laboratory on the side of the university also has the sign of 'High Precision Testing Laboratory'. Even the leadership of Zhengyang University doesn't know what kind of 'testing' it is, but it doesn't know. hinder their joy at the establishment of the laboratory.

When new research is conducted in universities, there are many benefits to the universities.

First of all, there are many top professors and experts who come to work in the laboratory, some of which are not even accessible to universities.

In addition, the university is also looking forward to seeing the well-decorated equipment being moved into the laboratory.

Research is only one aspect of expectations, even an unimportant aspect.

The most important thing is the laboratory.

In fact, few people at Zhengyang University know exactly what kind of research is being done, and the project was initiated by Zhao Yi and is only listed in the university, so it is difficult to say what to expect from the research.

However, the laboratory is real. After the project is launched, the laboratory is quickly established. What happens after the project is completed?

The lab is definitely still there.

At that time, even if some of the ultra-precision equipment is moved away, it can be rebuilt according to the framework of the laboratory.

The university is equivalent to having an extra high-end laboratory. Relying on a high-end laboratory, it can continue to conduct a lot of professional research.

It doesn’t matter what awards you can get for research, but maintaining a key discipline is enough.

By then, the School of Mechanical Engineering will also have a key discipline, and the development of the university will definitely get better and better.

This is a real benefit!

——

Zhao Yi doesn't care about Zhengyang University. What benefits he can get from research and laboratories, even if he knows, he will feel very good.

After all, Zhengyang University is a university in his hometown, and he hopes that his hometown can develop better.

While working in the new laboratory, Zhao Yi still has many things to care about, the most important of which is the progress of energy-gathering satellites.

The second energy-gathering satellite successfully entered the established orbit and began normal operation, continuously transmitting solar energy to the outside world.

This is a big event.

Zhao Yi also paid attention to other energy-gathering satellites. After completing the second round of financing, Yixing carried out large-scale expansion and ordered ten energy-gathering satellites in one go.

The satellites currently being ordered are being built as quickly as possible. However, the energy-gathering satellites are not yet ready for large-scale production. Each satellite takes more than one and a half months. However, because of relevant experience, some components that can be built on a large scale have also begun to be built on a large scale. ization, the construction speed has also been improved a lot.

At the same time, the cost of energy-gathering satellites has also declined.

Now, Yixing only needs to pay RMB 2.2 billion to purchase a power-gathering satellite. After negotiating with several cooperative companies, it has been determined that the subsequent purchase price will continue to be reduced, and the next batch of orders can be reduced to RMB 2 billion for a single seat. one time.

This cost is relatively cheaper.

For Yixing Company, energy-gathering satellites are the lifeline of energy. The more satellites, the better. No matter how many satellites there are, they are simply not enough, but there is still a plan to build the number.

"In the next three years, increase the number to thirty!"

This is the construction plan negotiated between Yixing and several partner companies.

The most important one is Advanced Compressed Materials Company, which needs to provide compressed materials for many projects, including the core spacecraft project.

If Advanced Compression Materials Company wants to improve manufacturing efficiency, it must manufacture a new Z-wave compression device, but it will definitely take time to manufacture a new device.

The efficiency of high-grade compressed material companies directly determines the efficiency of energy-gathering satellite construction.

Yixing can talk about "three years, thirty seats", which is already a limit number, because at the same time they also need a high-end compressed material company to manufacture compressed monocrystalline silicon in large quantities to produce light energy receivers for unlimited power cars. Converter.

At the same time, the world is also focusing on orbiting solar energy-concentrating satellites.

Energy-gathering satellites around the sun have always attracted attention, and they have become popular recently mainly because solar probes launched by other countries have taken close-up photos of energy-gathering satellites flying to the sun.

In addition, the detector also captured images of the operation of the energy-gathering satellite.

Although the picture is very unclear, just a small black dot, it is clearly visible that the energy-gathering satellite is almost orbiting close to the sun.

Some experts immediately stood up and said, "The normal temperature in the orbit where the energy-gathering satellite operates may exceed one thousand degrees Celsius."

"At the same time, we also have to face super strong solar radiation, magnetic field storms, high-energy radio particles, etc. In such a harsh environment, the energy-gathering satellite is still operating normally. How can this be done?"

"Material!"

In fact, the international community has long known that China has unique compressed material technology, and many foreign institutions have obtained compressed material samples.

It's no secret.

Many countries are involved in the external manufacturing of the spacecraft project, and the manufacturing of many parts requires the use of compressed materials.

In addition, the core of the infinite power car, the light energy receiving converter, also requires the use of five times compressed monocrystalline silicon wafers.

When various institutions tested the materials in their hands, they were surprised to discover the high physical properties of the materials.

One organization obtained the compressed nickel-iron alloy and found that they could not detect the melting point of the nickel-iron alloy using conventional means.

"Its melting point reaches at least 15,000 degrees Celsius!"

"An environment of 15,000 degrees Celsius is not something that can be maintained conventionally."

Some laboratories will claim that they can create a high-temperature environment of hundreds of thousands or millions of degrees Celsius. In fact, hundreds of thousands or millions of degrees Celsius is just a theoretical data. The measurement standard is particle activity, but it does not talk about 'particles'. quantity'.

It's just particle activity, but it doesn't mean much.

For example, water vapor.

Theoretically, water vapor is over 100 degrees Celsius. If you quickly draw your hand through the water vapor, you will only feel warm and will not directly burn your arm. (Warning: This is just an example. Please do not experiment. The author is not responsible for any consequences.)

If the water vapor becomes very thin, it is even less 'powerful'.

This is because of the particle density. When the density is insufficient, it is meaningless no matter how high the particle activity is.

The same goes for the original nuclear fusion device. Some laboratories claim that nuclear fusion can create an environment of over 100 million degrees Celsius. But if it is really over 100 million degrees Celsius, it is impossible for any device to maintain it. 'Over 100 million degrees Celsius' refers to particles. It is determined by activity, rather than a matter of actual detection.

Therefore, it is not easy to create a real high temperature of 15,000 degrees Celsius using conventional experimental methods.

New compression materials with ultra-high physical properties have shocked various institutions.

At the same time, a research report from the Institute of Mechanics and the Precision Optics Laboratory also revealed the principle of new compression materials.

"In our research on Z waves, we found that the principle why Z waves can make particles active is that they can compress particles."

"This kind of compression is elastic when the magnification ratio is below a certain level. That is, after compression, the particles will quickly return to their original state."

"But we believe that when the magnification reaches a certain level, the steady state of compression can be guaranteed."

"This is probably the secret of Advanced Compressed Materials Company's manufacturing of compressed materials."

This statement is very close.

The research reports of the Institute of Mechanics and the Precision Optics Laboratory did not mention the compression of space, but the principle was very close to the truth.

It is indeed remarkable that the research can be carried out to this extent by relying on the space cover to accumulate and release Z waves.

In response to the research reports of foreign institutions, a special meeting was held in China to discuss, and it was believed that continuing to keep them confidential had lost its meaning.

So Advanced Compression Materials Company published a technical report explaining the principle of Z-wave compression technology.

This report was published in a domestic magazine, but it caused a sensation in the international academic community.

The principle of Z-wave compression technology is simply to use Z-wave to compress materials. When compressed to a certain magnification, the material can maintain a steady state at the magnification level without being affected by space compression.

The relevant technical report did not mention Zhao Yi's name, but as long as we carefully analyze the technical principles, we will find that it must be related to Zhao Yi.

Because, space is squeezed.

This term appeared in the "Discourse on Mass Points" published by Zhao Yi and Edward Witten. The most basic source is also the boundary theory of particles. Space was proposed by Zhao Yi and can be directly distinguished from Zhao Yi's physical theory. equal sign.

After the technical report was published, it caused a lot of discussion, "It turned out to be researched by Dashen Zhao."

"It should be prefixed with 'Sure enough'!"

"This latest technology must be related to Zhao Dashen. Zhao Dashen is the leader who brings about the rapid development of human science and technology!"

"With this kind of compression technology, no wonder we can create energy-gathering satellites around the sun, and no wonder we can start the spacecraft project!"

"In the field of exploring the universe, material technology is the most critical. Now that there are new material technologies, only technologies related to exploring the universe can develop rapidly!"

“But doesn’t this mean making the technology public?”

of course not.

Many people are worried that other institutions will have compressed material technology after knowing the technical principles. But in fact, the principle of compressed material technology is not important at all. What is important is the Z-wave generation technology.

Research reports from the Institute of Mechanics and the Precision Optics Laboratory only speculate that "compression to a certain magnification can be maintained."

The reason why it is 'speculation' is because they can only release Z waves by accumulating energy through the space cover.

The Z wave released in this way has a very low energy density and cannot be used to create high-strength compressed materials. The compressed particles will quickly return to their original state after the Z wave effect ends.

Now other institutions can only discuss it. Without the most basic Z-wave generation technology, everything is meaningless.

On the other hand, as long as you have Z-wave generation technology, everything can be easily researched.

Other institutions also know the reason why they cannot study it. The main reason is that they lack relevant theoretical support. Without theory and knowing the principle of Z wave formation, it is impossible to create a Z wave generating device.

Even if they are given a Z-wave generating device, it will be very difficult for them to copy it. If there are some minor problems, the device will become irreparable.

So many institutions came forward again, hoping that the underlying theory of Z-wave technology could be disclosed in China.

That is of course impossible.

The underlying theory of Z-wave technology is absolutely confidential and cannot really be made public. However, Zhao Yi still published a paper, and it was a long paper. The paper was 230 pages long, and its name was also very ambitious. It was called "Space and Cosmology".

"Space and Cosmology" is a book.

Zhao Yi did not publish it in a magazine, but asked the publishing house to print it directly. While publishing his theory, he could also earn some copyright fees, which was a double benefit.

"Space and Cosmology" starts from the perspective of Z-wave compressed materials and expands to talk about the relationship between space and the universe, thus forming a brand new theory of universe development.

In the first part, the style of previous papers is still continued. There are many introductions and direct mathematical proofs, all directly related to compressed materials. The proofs made in it are related to the compression limit magnification.

Many international academic institutions are talking about the issue of compression limit magnification.

This time, it was directly disclosed. The internationally known compression limit ratio is the constant ‘e’.

"When the compression ratio of particles reaches e, they can maintain the balance with space extrusion through the magnetic field and force field formed by themselves, and will no longer be affected by the related effects."

“Here, the ‘magnification of e’ is called the steady-state space limit constant.”

"At the same time, when the compression ratio reaches the π power of e, it will enter a new state, and the particles will continuously release zero-state Z waves to compress and absorb the space."

"So, the compression ratio of e to the power of π can be called the 'anti-space limit constant'."

"When a large number of particles reaching the ultimate space constant are gathered together, they can continuously compress space, absorb energy, and even distort time and space——"

"I think this is what black holes are like."