Genius of the Rules-Style System

Chapter 601 The critical value of particle compression ratio

Zhao Yi heard Fan Lei's shout and came up with an idea about the relationship between particles absorbing energy and space. After returning home, the more he thought about it, the more it made sense.

However, because it is just an idea, it cannot be directly confirmed by the Law of Causality. More research or experimental data are needed as conditions.

Zhao Yi wrote down his thoughts and did not rush to do research. Instead, he stayed at home with Lin Xiaoqing and lived a sweet life for a few days, looking forward to the birth of his child together.

It was not until three days later that he decided to return to the experimental group and start related research.

When he returned to the experimental group this time, Zhao Yi's research was very clear. He immediately told the experimental group to prepare new experiments and made an experimental report to his superiors. He planned to use a month to conduct seven consecutive Z-wave shock experiments.

High-frequency experiments are related to the research purpose. He hopes to use continuous experiments to find the 'critical value' of particle absorption energy against space absorption.

Under about five times the compression effect, after the superconducting material enters the superconducting state, it cannot be detected to have anti-gravity properties, and the superconducting anti-gravity experiment has no results.

This must be directly related to the energy absorbed by the particles.

Then we can continue to think deeply. Is the performance of superconducting materials related to the rate at which they are compressed?

By compressing it five times, the superconducting anti-gravity properties cannot be demonstrated.

How about three times?

What about twice as much?

Or will particles that are only a few tenths of the time completely resist space absorption?

Zhao Yi convened the core members of the theoretical team and talked about his thoughts, "Now we are not sure whether the five-fold superconducting material will have no anti-gravity properties at all when it enters the superconducting state."

"Because there is still a possibility that the material has extremely small anti-gravity properties, but our experiments are not strong enough and cannot be detected at all."

This is indeed a possibility.

Some data show a power level decrease, which is the opposite of exponential growth. The high rate of decrease also causes the data to decrease to a certain extent, which cannot be detected by experiments.

The antigravity properties of superconducting materials may also have a similar situation.

For example, if it is compressed twice, it will only have 3% anti-gravity properties.

And after five times of compression, the anti-gravity properties may only be 0.3% or less, and the experiment cannot detect it at all.

Then it is very necessary to conduct a series of compression superconducting material experiments at different magnifications. What the experimental team needs to do is to obtain experiments with different compression magnifications to see whether the anti-gravity properties of low-magnification superconducting materials can be detected. At the same time, the relationship between compression ratio and anti-gravity characteristics is also studied.

Although Zhao Yi said that there is a possibility that the anti-gravity characteristics will decrease at a power level, he is more inclined to another possibility, which is that there is a critical value for compressed particles to resist space absorption.

When the particles are compressed at a certain rate, they will have complete resistance to space absorption.

The two are different.

If we consider the relationship between the anti-space absorption capacity of particles and the compression ratio of the particles, and make a curve function and reflect it on a plane for analysis, the former is a curve function that decreases in power level. No matter how high the compression ratio of the particles is, the function will never match the coordinates. The latter also decreases rapidly, but at a certain value, it directly intersects with the coordinate axis. If it continues to increase, it may be parallel to the coordinate axis, or at a certain value, it may directly break away from the coordinate axis and continue downward. .

Zhao Yi summoned the core members of the theoretical team and explained the continuous experiments, which immediately sparked a heated discussion. Once they understood why the experiments were conducted, everyone was looking forward to the experiments.

Where the energy absorbed by particles goes is definitely an important topic in Z-wave space compression research.

The conclusion of this research will definitely challenge the mass-energy equation, and may also reveal some deep secrets of the rules of the universe.

Everyone is looking forward to it and everyone is very motivated at work.

The preparation for the experiment is relatively simple.

Because only superconducting materials are compressed, there is very little material in the experimental coverage area. Z waves of the same intensity will greatly increase the compression ratio.

According to calculations by the theoretical team, the Z-wave intensity of the second experiment will even increase the space compression factor to about 20 times, which means that the superconducting material will be compressed 20 times.

This is absolutely an amazing value.

However, the experiment is not to perform high-intensity space compression on superconducting materials, but to perform lower-intensity compression in order to detect the superconducting anti-gravity properties of the compressed superconducting materials.

So the compression ratio is determined to be between one and five times.

Then the release intensity of the Z-wave experiment can be said to show an exponential decrease, even if it is the same five-fold compression, because there is only superconducting material in the area. Compared with the second experiment, the intensity of the Z-wave release can also be reduced by eighty times. More than times.

Because most of the energy in the Z-wave release device is used to start the device, the intensity of the Z-wave release is not directly proportional to the energy consumption. However, because the intensity of the release is low, the energy consumption will be greatly reduced, and only the power generation of the experimental group is required. The machine is complete enough.

Therefore, the scale of the experiment is still very small and will not affect the surrounding areas. After submitting the application report, the superiors directly approved it. At the same time, they also gave permission, indicating that small experiments used for theoretical research only require experiments. You can just make a report later, and there is no need to apply for experiments again.

While the Z-wave experimental team was conducting experiments in full swing, high-level departments also held continuous meetings about Z-wave experiments, space compression materials, and spacecraft plans.

Among them, the new materials produced by Z-wave experiments are the key.

High-end material manufacturing is really important.

For the development of science and technology in various fields, the first thing that needs to be used is materials. From space exploration to chip manufacturing, material technology is very critical.

There has always been a gap between the domestic manufacturing level of high-end materials and that of the country. High-end materials in many fields cannot be manufactured at all and must be purchased from abroad.

For example, aviation manufacturing.

Some domestically developed aircraft even rely on imported materials for their skins.

Therefore, the technological development of high-end material manufacturing has always been an area of ​​focus. There is an international saying that it will take at least several decades of development for domestic material manufacturing to catch up with the international top.

This is a fact.

In the past, even if the country did not accept it, there was nothing that could be done, but now a solution suddenly came out.

The development of science and technology has always emphasized overtaking in corners, because if you follow the path that others have taken, there may be some set obstacles ahead, making it almost impossible to catch up.

Now a new type of high-end material manufacturing technology has suddenly appeared, and the physical properties of the materials produced by this technology easily exceed the world's top, and even reach incredible levels, so it has naturally become a top priority for research and development.

High-level departments held a meeting on Z-wave compression technology, focusing on the production of ultra-high-performance ‘compression materials’.

After Ruan Wenye, the representative of the experimental group, made a relevant summary and presented a nickel-iron alloy with a melting point of over 10,000 degrees Celsius, the meeting almost unanimously passed the decision to increase investment in research and development of Z-wave technology and the development of compressed materials.

This is the use of Z-wave generators to specifically manufacture compressed materials used in various fields.

Of course.

It will still be used internally in the short term. Only when the technology truly matures will it be considered for development into the civilian field.

So the experimental team separated several people and worked with other departments to build a second large-scale Z-wave generator, specifically used to study compressed materials.

The experimental group did not change much, just sending a few people to help and explain.

Ruan Wenye is the leader of the overseas team. Ruan Wenye is responsible for external work, so he has temporarily left the theory team.

However, Ruan Wenye's departure does not seem to have any impact, because the core of the experimental group is still a limited number of people such as Zhao Yi and Zhang Qican. The mathematical physics experts from the Institute of High Energy and the Academy of Sciences who later joined also have a deep understanding of Z-wave theory. Ruan Wenye His ability level is relatively mediocre.

After that, high-level departments held several meetings in succession, all of which discussed the Z-wave experimental team, material technology, and the spaceship program. However, there was not much discussion on the spaceship program. The main reason is that there are two reasons. One is space. The spaceship plan is too huge and involves too many technologies. The huge research and development plan and fund mobilization are all problems, and it must be steadily advanced step by step.

The second is that the spaceship program still lacks core technology--

Nuclear fusion device.

There are no problems with technology and design in the current research and development of nuclear fusion devices. The key to the problem lies in the materials, especially the parts in contact with the internal reaction and the output end. The materials are all unqualified and cannot withstand high temperature, high pressure, etc. for a long time. High radiation environment.

If the properties of the materials are not up to standard, the fusion device cannot operate all the time.

Chen Zeshu has always been troubled by the problem of materials, but what he did not expect was that when he was invited to a high-level department meeting, he would get such a message, "Professor Ruan, the nickel-iron alloy you mentioned at the meeting has a melting point of more than 10,000 degrees Celsius. It is true." ?"

This data is amazing.

Ruan Wenye came to the meeting and introduced the materials very calmly, which immediately shocked everyone.

Melting point is 10,000 degrees Celsius, what is the concept?

Even the alloy with the highest melting point is only just over 4,000 degrees Celsius. Research shows that the core temperature of the earth is only 4,000 to 7,000 degrees Celsius, and the surface of the sun is 5,500 degrees Celsius.

There is obviously a big gap between these data and 10,000 degrees Celsius.

In other words, the nickel-iron alloy displayed by Ruan Wenye will not melt when placed in the core of the earth or on the surface of the sun. It is not easy to dissolve it using technological means.

Ruan Wenye nodded affirmatively, "Academician Chen, it is impossible for me to lie about this kind of meeting, and even if I lie, it cannot be so outrageous."

Chen Zeshu apologized, "I'm not questioning you, it's just too amazing. Your Z-wave experimental group was created using Z-wave technology, right? Academician Zhao told me last time that his research was related to material manufacturing. I didn't expect it. Really."

"This alloy may be used in our nuclear fusion devices. After being melted and applied to the outer layer of the space cover, it can increase the safety of the equipment."

"You also know that what our team lacks most is high-end materials——"

Chen Zeshu said a lot in succession.

Ruan Wenye listened for a long time before he understood that Chen Zeshu valued the materials in his hand, but was too embarrassed to ask for them directly. He said with a smile, "Academician Chen, nuclear fusion research is a key project, and Academician Zhao is also very concerned about it. What else do you need?" , you can contact the experimental group to solve it. In addition, it was not mentioned at the meeting that a new large-scale Z-wave device will be built specifically for compressed material research. The Z-wave device of our group is mainly used for theoretical research."

"I know too." Chen Zeshu said sheepishly, "Isn't it because I can't wait? Okay, when I get back I'll let you -"

"Forget it, why don't I go directly to the experimental team?"

Many materials for nuclear fusion experimental devices are unqualified, but internationally, it is impossible to find suitable materials because the requirements are too high.

For example, the output.

Because the output end is not covered by the space cover, it will be impacted by neutrons. The neutron impact in nuclear fusion is much more powerful than ordinary radiation, and materials have high requirements for radiation resistance.

At the same time, the output end also has to withstand high temperature and pressure. The nuclear fusion research team has demonstrated that the section that contacts the internal reaction needs to withstand a minimum temperature of 3,000 degrees Celsius.

Even if a material with a melting point of 3,000 degrees Celsius and strong radiation resistance is used, it is difficult to say that it is qualified, because the material needs to withstand harsh environments for a long time, and it does not stop, so it must be guaranteed to react without any damage.

Therefore, the material is required to have a higher melting point and stronger radiation resistance. It can be said that it is at least one level stronger than the minimum requirements.

This material arguably does not exist.

After the meeting, Chen Zeshu continued to participate in two small meetings, and when he had free time, he immediately decided to join the experimental group.

He first conducted direct dialogue and inquiries with the people in the experimental group.

Chen Zeshu wanted to find Zhao Yi, but it turned out that Zhao Yi was doing research patiently. He couldn't wait and simply told the technicians who contacted him. After hearing Chen Zeshu's series of requests, the technicians felt a headache, and they directly replied, "If you can If you apply for a special experiment, your group can transport the materials originally used to the experimental group, and then conduct a special experiment. After compression, the physical properties of the material will be greatly enhanced, and it may be able to meet the requirements."

This reply surprised Chen Zeshu. He didn't understand the method of making materials for the Z-wave experiment, so he simply agreed and applied, and then went directly to the location of the Z-wave experiment team.

At this time, the experimental team was conducting frequent compression experiments on superconducting materials. Zhao Yi led the theoretical team to conduct a series of conclusion analyzes based on the experimental results.

Five experiments have been completed. After conducting five experiments, the experimental team encountered a problem. There was a problem with the internal generating device of the large Z-wave generator, and the parts had to be replaced.

After the technical team discovered the problem, they made a report on the fault. "Because the Z wave will affect the generating device, some components are affected and compressed, causing serious damage to the internal seal of the generating device."

This problem has been thought of before, but because of continuous experiments, it has not been taken seriously.

It must be taken seriously now.

Zhao Yi decided to replace the temporary parts and conduct a large-scale experiment. "Even if it is only done once, we will use this experiment to create relevant compression materials to protect the Z-wave generating device."

This approach is to update the material components of the Z-wave generator.

After the relevant components are updated, the Z-wave generating device's ability to withstand Z-wave impact will be greatly enhanced, making it difficult for similar damage to occur in the future.

There is a saying that sharpening the knife does not waste time cutting wood. Do the work well first, and then conduct relevant experiments. The experiments will be more frequent and the experimental data will become more accurate.

at the same time.

The past five experiments were enough for Zhao Yi to figure out the rate at which particles can resist space compression.

The theoretical team used six experimental data before and after to come up with two possible results.

When the superconducting material is compressed 2.9 times, the anti-gravity properties of the superconducting state cannot be detected. At the same time, when the superconducting material is compressed 2.1 times, the weak anti-gravity properties of the superconducting state can be detected.

Zhang Qican concluded the research, "So, one possibility is that the particles are compressed against space absorption, showing a power level reduction. If it exceeds about 2.2 times, it can no longer be detected."

"In addition, there is another possibility that there is a magnification number between 2.1 and 2.9 that allows the particles to completely resist the spatial absorption properties."

These are two analysis results.

Zhao Yi used his causal thinking ability to get a more accurate conclusion. There is indeed a 'critical value' for compressed particles to resist space absorption. When the critical value is exceeded, the particle's ability to resist space absorption will reach a balance with space compression. .

This balance is like a shield, which can directly resist cuts by swords, because the sharpness of the sword is fixed. No matter how strong the shield is, it will still be placed there, and it will still be unbreakable. In a practical sense, Even so, it still balances with the cuts of the sword.

Zhao Yi obtained the critical value for particle compression, which is more precise than the experimentally inferred data, ranging from 2.65 to 2.73.

For numbers in this range, you can immediately think of a special one——

The natural constant, e, e is approximately equal to 2.718.

Create a question——

[Is the lowest rate (critical value) at which compressed particles resist space absorption and reach equilibrium equal to the natural constant e? 】

【A.Equal. 】

【B. Not equal. 】

["Law of Cause and Effect"! 】

[Answer: A. 】

I still feel uncomfortable today and have been feeling uncomfortable for a long time. I will finish yesterday’s chapter tomorrow. Feel sorry.

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