In the office.

The people in the research team kept discussing and recording that they were studying possible special phenomena, but they never thought that a theoretical framework could be created.

Although it is only a few words and does not fill in enough mathematical foundations, overall, it already has a general theoretical framework.

The name of this theory is "The Development of the Universe and the Properties of Elements".

The main content of the theory is that as the annihilation force in the universe continues to increase, the properties of elements are also constantly changing.

For example, regular iron.

Conventional iron elements are stable and not radioactive. Iron elements have several isotopes, three of which are radioactive.

, their atomic mass numbers are respectively.

After countless years of evolution, in a cosmic environment with enhanced annihilation power, perhaps a certain isotope has become a stable element in the process of constant change.

Of course, the above are just examples.

What the new theory wants to express is that an element in a stable state under a conventional annihilation force environment may become a decaying element after tens of billions of years of natural evolution.

Through long-term natural evolution, some decaying elements have the same behavior.

may become stable.

The new theory is related to the annihilation force field experiment and upgraded elements. It is believed that there is a deviation between the elements that are upgraded under the action of a sudden increase in annihilation force and the elements that naturally evolve with the increase in annihilation force.

The difference between the two is a peculiar phenomenon.

"This peculiar phenomenon may be a special magnetic field, some undetected rays, or other manifestations..."

"But in any case, the existence of special phenomena has played a role in resisting the strong annihilation force field."

Paul Field-Jones said, "I still prefer specific magnetic fields, because experiments have proven that magnetic fields have a repulsive effect on strong annihilation force fields."

"The existence of some special magnetic field may weaken the effect of the annihilation force field within a certain range."

The point put forward by Paul Phil-Jones is indeed very reasonable, and directly explains the problem of the fixed first-order iron content of raw materials under a strong annihilation force field.

But how to prove it?

Wang Hao can't think of it yet. The only thing he can think of is...

nuclear testing.

It’s the same as what Ding Zhiqiang said.

Finally, Wang Hao looked at Ding Zhiqiang. Paul Phil-Jones and Helen also looked at Ding Zhiqiang, hoping that Ding Zhiqiang would have some good ideas.

Ding Zhiqiang....

He shrugged and said nothing.

Wang Hao, Paul Phil-Jones, and what Helen said, Ding Xingtian fights.

Zhiqiang can understand it. Because of this, he is going through a process in his heart.

If Wang Hao had just forced himself to say he was a genius, Ding Zhiqiang would have immediately classified him as a "positive PUA."

Now…………

This is true for both Paul and Helen.

The problem is that Ding Zhiqiang felt that what they said was very reasonable. He thought along the lines of "nuclear experiments" and completed a theoretical framework.

When he thought of this, Ding Zhiqiang felt that he was a genius.

He told the result directly!

Wouldn't it be possible to conduct a nuclear test under a strong annihilation force field to prove all the inferences? At that time, it was just a casual comment, but it led to a large set of analysis.

The final problem still comes down to nuclear experiments.

It's like answering a super difficult question. He tells the answer directly, and others get inspiration based on the answer, and then slowly work backwards...

When Ding Zhiqiang thought about it carefully, he couldn't help but doubt, "Am I really a genius? It's impossible...

"Why don't I feel it myself?

"When it comes to IQ, Teacher Wang Hao

Helen, Paul...ahem, there is no comparison at all. Speaking of others...what else?"

He was confused as he thought.

the other side.

Tian Guilin, Liao Zhenxing and Wang Zhimin did not say a word during the whole process, they just sat aside and listened quietly.

They were initially shocked by the content such as "the discovery of first-order lithium, and its extremely high content." Later, when they actually entered the discussion, they found that they could not speak at all.

Another reason is that they feel that their IQ is completely unable to keep up, and they are deeply shocked.

Mr. Jones made a complicated statement, but Ms. Hinton could react instantly, and then continued on, saying that she didn't quite understand.

have a look!

Can you add some personal opinions?

Doesn't she have to think?

The little fat guy named Ding Zhiqiang is even more powerful. He is indeed Academician Wang Hao's most valued student. He is simply a genius to the extreme.

While others were still thinking about the derivation, the little fat man had already come up with the conclusion. It was like doing a super difficult calculation problem. It would be great if you could find a way to calculate it. As a result, someone directly gave the answer.

Although they didn't quite understand it, they still felt it was very powerful.

Didn't you see it?

Mr. Jones, Ms. Hinton, and Academician Wang Hao all gave the little fat man a thumbs up. When they had questions, they all looked at the little fat man...

wrong!

Never call me fat boy from now on!

Want to call………………

"Professor Ding!

After the discussion of the research group ended, Wang Hao, Helen and Paul Phil-Jones all left. Liao Zhenxing and Wang Zhimin immediately surrounded Ding Zhiqiang, "Professor Ding, I heard your name when I was at the Institute of High Energy.

It’s like thunder piercing my ears!”

"Professor Ding, you are truly a genius. We need to learn more from you. Can you recommend some information to us?"

"Professor Ding, what are you studying? Can we help?"

"Professor Ding..."

Tian Guilin stood at the door with his hands behind his back, watching, and couldn't help but sigh in his heart, "Zhenxing and Zhimin are really smart."

"Although Professor Ding is still young, he is a formidable young man. If they stay here and discuss with Professor Ding more, they will surely learn a lot."

"As expected of Academician Wang Hao's most valued student...

While Wang Hao's research group was immersed in the study of special phenomena, the international physics community launched a fierce scientific research competition around first-order iron.

This chapter is not finished yet, please click on the next page to continue reading the exciting content! "Measurement of First-Order Iron Radiation Waves".

"Method of creating first-order energy waves by exciting radiation".

"Precision Measurement of the Melting Point of First-Order Iron".

"A steel made of ultra-low carbon content first-order iron". "Normal environment first-order iron...".

Every issue of the top international physics journals will have results related to "first-order iron". There are many institutions that have a large amount of first-order iron materials.

Researchers work day and night to make new discoveries faster.

At the same time, there have also been many results related to first-order iron research.

Most of the results focus on physical properties, radiation properties and electromagnetic properties, and some are theoretical studies that make inferences based on experimental results.

etc.

Some powerful materials institutions are making progress in first-order ferroalloy research

It has developed rapidly and continuously launched results related to first-order ferroalloys.

For example, the Aerospace Materials Institute uses first-order iron as raw material to create a low-carbon steel with a toughness of up to 1,450 MPa and a Rockwell hardness of 75.

This data is not the toughest among steels, but the results released by the Aerospace Materials Institute only illustrate a problem. "The steel we made using conventional iron as raw material and the same method has a toughness of 1230 MPa and a Rockwell hardness of 63."

"Switching to first-grade iron, the toughness and Rockwell hardness have been greatly improved."

"In the direction of alloy manufacturing, first-order iron is used to replace ordinary

Gauge iron, the steel produced has stronger toughness and hardness.”

Several top materials institutions have released similar results, including the Wuhan Iron and Steel Research Institute, the Fucheng Shipbuilding Industry Steel Research Group, the Technology Department of Locke Lisman Steel Company, the Metal Materials Research Institute of the Max Planck Society, and so on.

Putting these results together, we can make a simple summary. The toughness and hardness of steel made with first-order iron instead of iron will be greatly improved, and the improvement range is between %.

This effect has been very significant.
To be continued...