From University Lecturer to Chief Academician

Chapter 422 Publication of the results, first-order carbon: the beginning of the sublimation of huma

Liu Yunli guessed right.

Wang Hao is really confident in the verification of DC anti-gravity characteristics, and he predicts that there will be materials that meet the requirements of DC anti-gravity.

This is not a simple estimate, but a conclusion drawn from experience.

So far, only two high-voltage hybrid materials have been used in the research of DC anti-gravity, which seems to be completely unrelated to metal superconducting materials, but a little correlation can still be found.

For example, both high-pressure hybrid materials have AC superconducting anti-gravity properties.

This leads to an imprecise conclusion that materials with DC anti-gravity properties must have AC superconducting anti-gravity properties.

From the research on the antigravity characteristics of first-order iron superconducting materials, it can also be found that whether it can stimulate the antigravity characteristics before reaching the superconducting state has a certain relationship with the chemical bonds of metal compounds.

Before there is enough data to support it, it is impossible to draw conclusions from similar studies, but some conclusions that are not rigorous and may be of great help to experiments are still obtained.

For example, the covalent bond of first-order iron.

There are three types of chemical bonds between the atoms of a compound, one is an ionic bond, one is a covalent bond, and the last is a metallic bond.

Ionic bonds are formed by the transfer of electrons between atoms to form positive and negative ions, which are formed by electrostatic interactions.

Metal bonds, which mainly occur in metals, are formed by the combination of free electrons and the electrostatic attraction between metal ions arranged in a lattice.

A covalent bond is when two or more atoms use their outer electrons together, ideally reaching a state of electron saturation, thus forming a relatively stable chemical structure.

The essence of the covalent bond is the electrical interaction between the electrons that appear between the two nuclei with a high probability after the atomic orbital overlaps and the two nuclei.

Based on the data of the anti-gravity property experiment and the analysis of the elemental composition of the compound, a conclusion can be drawn--

The more covalent bonds formed by the first-order iron, the more likely it is to excite the antigravity field at a temperature higher than the critical temperature.

This conclusion is very imprecise.

However, Wang Hao can confirm that materials containing first-order iron excite antigravity fields and covalent bonds through "correct feedback".

Of course, there are many factors associated with anti-gravity properties.

Covalent bonds are just one of them.

Among various related factors, the importance of covalent bonds is also difficult to judge. Because of this, Wang Hao's remarks are "maybe one or two".

He is still very much looking forward to the experiment.

The next step is continuous experimental preparation. It is very complicated work to verify the DC anti-gravity characteristics of each material.

DC anti-gravity is much more complicated than AC superconducting anti-gravity.

If the material layout design difficulty of AC superconducting anti-gravity is rated as '100', then the difficulty of work related to DC anti-gravity will reach '300, 400', or even more.

Experiment preparation is time-consuming.

After more than two weeks of hard work, they verified the most anticipated FCW-031. In the AC superconducting anti-gravity experiment, the anti-gravity field strength excited by FCW-031 reached 7%. The median value is the highest.

Unfortunately.

The final experimental results show that FCW-031 does not have DC anti-gravity characteristics.

When many data analysis tasks were completed and Wang Hao confirmed the results, disappointment came from the conference room.

"FCW-031 does not have DC anti-gravity characteristics? It is the most promising."

"Failure is also normal..."

"But it's still frustrating, we've done so much work."

Liao Jianguo was sitting next to Liu Yunli. He turned his head and whispered, "Professor Liu, what do you say now? The experiment failed."

Liu Yunli glanced at Wang Hao, and replied calmly, "What's the big deal, we have to experiment with several materials, but only the first one."

"I hope..."

Wang Hao was also very calm, he announced, "Get ready for the next experiment."

"Let's try material No. 25 (FCW-025). This material with first-order iron and first-order lithium is very special, and it may have DC anti-gravity properties."

FCW-025 contains first-order iron and first-order lithium, and is a very complex metal compound.

At the same time, FCW-025 is also the weakest antigravity field among several materials, and its superconducting state is only 0.58%.

This material is used to test DC anti-gravity properties...

"Can it work?"

"Academician Wang said to try it, I think there may be hope."

"Material No. 25 is indeed very special, with the most complex element composition, and at the same time, the excited antigravity field is the lowest."

"First the highest is 31, and then the lowest is 25. Academician Wang arranges experiments regularly."

"Just follow along..."

...

While Wang Hao was concentrating on the verification of material properties, public opinion at home and abroad was already boiling over the new discoveries made by the annihilation force field experiment group.

"Physics and Theory of Annihilation" has released a new issue.

The first article was titled "New Discovery of Upgraded Materials: First-order Carbon Elements", which quickly attracted the attention of scholars in all concerned journals.

Soon the news made its way out of academia.

Many media that pay attention to the study of strong annihilation force fields have reported on the discovery of first-order carbon, and several of them are international media with great influence, and each headline is very eye-catching--

"Wang Hao's team discovered the first-order carbon, and the third element is actually a non-metal! "

"The most important upgrade element is discovered! "

"This year's biggest physics achievement is the way out, first-order carbon is far more important than first-order lithium! "

First-order carbon: the beginning of human sublimation! "

"The discovery of first-order carbon is destined to promote the development of scientific and technological breakthroughs!" "

"level one……"

The popularity of public opinion this time is much higher than when first-order lithium was discovered, mainly because carbon is so important.

The media has carried out a large number of reports, as well as a large number of commentary analysis.

Carbon is one of the most important elements.

For known living systems, carbon is indispensable. Without carbon, life cannot exist, and life on the earth is also called carbon-based life.

Some media analysis and reports start with the importance of carbon to life, and their analysis is very interesting.

They believe that the discovery of the first-order carbon element may sublimate the essence of human life.

"It is the most important building block of living organisms."

"If the ordinary carbon elements in the human body are replaced with first-class carbon elements, will the essence of human life be improved?"

"First-order elements have a higher 'order' than ordinary elements..."

"..."

This statement has no scientific basis, but it has aroused widespread heated discussions in public opinion. After all, the absence of scientific basis does not mean it is wrong.

Many people are discussing about "first-order carbon sublimates human beings", "If all carbon becomes first-order carbon, I will definitely become stronger."

"It's great to be strong. Fitness can do it. I think that the first-order carbon can make me superhuman and have some special abilities, such as emitting light waves."

"It may also be a fairy, or a god."

"I think the biggest possibility is that after the body has a large amount of first-order carbon, you will soon get cancer..."

"First-order carbons are likely to be toxic."

"What if the body adapts? It's hard to say. I've read research reports, saying that the chemical properties of upgraded elements are the same as ordinary elements..."

"That must be different."

"..."

Some media conduct analysis from a scientific point of view, and popularize some knowledge about carbon, so that more people can understand the application fields of first-order carbon.

In short, very broad.

Carbon exists widely in animals and plants, and the most important economic use is in the form of hydrocarbons, which are crude oil and natural gas.

In addition, carbon is an important component of alloy materials.

Carbon and iron can form alloys, the most common being carbon steel; graphite and clay can be mixed to make pencil leads for writing and drawing, and graphite can also be used as a lubricant and pigment, as a molding material for glass manufacturing, for electrodes and Electroplating, electroforming, brushes for electric motors, and neutron decelerating materials in nuclear reactors.

etc.

The application of carbon element is too extensive.

When the discovery of first-order carbon elements is confirmed, the research and application directions will be very extensive.

The academic community pays more attention to the short-term significance of the discovery of first-order carbon. For example, what direction of research can be done, first of all, alloys.

Carbon and iron can form alloys.

Then by relying on first-order carbon and first-order iron, it is possible to produce a first-order alloy material with a stable mentality, so what is the behavior of the first-order material?

This point has attracted much attention and has also aroused extensive discussion.

At the same time, some institutions engaged in the research of the annihilation force field pay more attention to the data behind the newly discovered results-the annihilation force field strength 8.36.

To put it bluntly...

The strong annihilation force field technology of Wang Hao's team has been improved again!

...

Virginia City, Nevada.

The Groom Lake project research group is conducting research and development seminars, and Fermilab's Roster Brook is making a report on the direction of first-order element alloys.

More than a dozen top scientists listened to Brook's report and discussed in a low voice from time to time.

George Wicks was one of them.

It's just that he completely dismissed Brook's report, because he didn't think that alloys made of first-order elements could replace high-pressure mixed materials to create a strong annihilation force field.

So far, they have only found a first-order iron alloy with anti-gravity properties, but the anti-gravity field produced is so weak that it can be ignored.

The same is not true for first-order iron compounds.

They developed two first-order iron superconducting materials, one of which produced an antigravity field with a strength of 0.93, and excited the antigravity field at a state of 50K higher than the critical temperature.

However, Gamow-Shapley was very stubborn and insisted on researching from the two directions of metal compounds and alloys, which cost a lot of money for no reason.

George Weeks looked up at Shapley and found that the other party was not listening to Brooke's report, but was staring at the computer screen in a daze.

The scholar next to him also noticed it, and reminded him in a low voice, "Mr. Shapley? Mr. Shapley!"

Shapley shuddered.

Everyone in the conference room looked over with doubts.

Gamow-Shapley raised his head in shock, took a deep breath, and said, "Now there is bad news and good news."

"The bad news is that Wang Hao's team has made a new discovery."

"The good news is that they found first-order carbon. If we get first-order carbon, we can use it to make pure first-order steels and study superconducting materials that contain more first-order elements."

The others were also shocked.

"First-order carbon?"

"Are you kidding me?"

"Really, look at the news, they published the results in "Annihilation Physics and Theory"..."

"It really is……"

"It can't be fake!"

Everyone discussed it.

They were really surprised.

Wang Hao's team is their direct competitor and goal of catching up. They have carefully analyzed the annihilation force field technology mastered by Wang Hao's team.

Putting together the information obtained in various ways, they believed that the annihilation force field technology of Wang Hao's team had reached a bottleneck.

It is very difficult to break through this bottleneck.

The proof is that in the past few months, Wang Hao's team has not announced any new discoveries, probably because the strength of the annihilation force field created has reached the upper limit.

Now……

Another breakthrough?

"8.36 ah!"

"It's about 0.3 higher than before. This improvement...will take a long time, right?"

The difference between the 8x ratio and the 8.36x ratio is not big, but it directly overturned their judgment on the technology mastered by Wang Hao's team.

The scholars in the conference room were immediately in no mood to listen to any more reports, but discussed the technology of Wang Hao's team, "Their improvement this time is very unusual."

"From 8 to 8.36, technical improvements can also be achieved. However, there is very little room for technical improvement to create a strong annihilation force field based on high-pressure mixed materials."

"I think they may have mastered the strong annihilation force field generation technology based on metal superconducting materials containing first-order iron!"

"There is such a possibility!"

"If so, will they continue to improve?"

"..."

Many scholars have no confidence in what they say.

Gamow-Shapley also felt the same way. They were confident in catching up with Wang Hao's team because they judged that the technology of Wang Hao's team had reached a bottleneck.

When competitors are no longer improving, it is only a matter of time to catch up.

What if competitors are still improving rapidly?

Catch up, there is no hope at all!

"They must be based on metal materials to study the generation technology of strong annihilation force field. So, the good news is that our research route is correct."

"Whether it is a metal compound or an alloy, there is hope..."

"Sorry, I have to leave."

Gamow-Shapley stood up after speaking, and he realized a very important problem.

The discovery of the first-order carbon was very important to their research.

If there is a first order of iron and a second order of carbon, they are more likely to develop metallic materials that can replace high-pressure hybrid materials.

The other party must know this question.

So will the first-order carbon be in the other party's sales list?

Gamow-Shapley quickly left the conference room, and immediately contacted his superiors and the Florist's technology department to try to discuss the issue of first-order carbon.

"First-order carbon is so important!"

"I just found out now that it will definitely be very expensive if the other party wants to sell it. If it is like first-order iron, it is impossible to buy it..."

"That's too expensive, $100 million a gram!"

Shapley looked bitter at the thought of the price.

The Groom Lake project has more than 50 billion U.S. dollars in support, which sounds like a very large research project, but in front of the price of "100 million U.S. dollars per gram", their funds are nothing at all.

In addition, not all funds are used to purchase materials.

Most of the funds still have to be invested in laboratory construction, employee salaries, and cooperation with corporate institutions.

Among them, employee salaries and plans account for more than one-third.

"However, we must obtain the first-order carbon. Even if we can't do research, we must know the characteristics of the first-order carbon."

"This can also be used to infer its potential for producing annihilation force field materials."

"This is the most important job right now!"

"..."

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