"The outer electrons of the first-order iron element are active. Under normal circumstances, it means that the compound formed will be unstable."
"But first-order iron compounds are more stable than conventional iron compounds..."
"Also, the superconducting material made of first-order iron can create a weak anti-gravity field if it exceeds the critical temperature by tens of K..."
"Electrons are extremely active, chemical properties..."
Wang Hao frowned and thought carefully. Putting all the findings together, he could clearly see the anomalies that were not in line with the norm.
But why?
"Could the abnormal activity of the outer electrons be related to the abnormal anti-gravity behavior of the material?" He continued to think, and suddenly thought of a possibility, "Or, the semi-topological structure may also have instability problems?"
Stability and instability are all relative.
The stable properties of first-order iron compounds do not mean that other properties will also be stable. The semi-topological structure formed by the conductive state and the self-selected ion lattice of the superconducting state may behave opposite to their chemically stable states.
The instability of semi-topological structures has long existed.
It turns out that when superposition force field technology is used to create a strong annihilation force field, the high-voltage hybrid superconducting material used makes the semi-topological structure formed in a conductive state unstable.
It is precisely because of the unstable structure that an anti-gravity field can be created before the superconducting state is reached.
It's like an orange with a notch on one side. When you knead it hard, a large amount of juice will spurt out from one side and create a certain impact on the outside.
"The semi-topological structure is also unstable now, but it's just more serious..."
"Perhaps there is not one gap, but multiple gaps, so an anti-gravity field can be created when the critical temperature exceeds tens of kilometres."
"These are just guesses..."
"If you want to understand the basic principles, you still need more experimental discoveries and more data support."
He thought about it and made a decision.
…
Research related to first-order elements is too important.
Including possible special phenomena, including outer electron activity inconsistent with the norm, including abnormal anti-gravity properties, etc.
These contain deep mysteries.
Wang Hao hoped to reveal the underlying principles, which required more experimental support, so he went directly to the Superconducting Materials Research Center.
After arriving at the research center, he saw Deng Huanshan and asked directly, "Is there any latest anti-gravity material made of first-order iron?"
"Newest?"
Deng Huanshan hesitated for a moment, then said, "There are only the original ones..."
"You haven't done any research yet?" Wang Hao complained, knowing that Deng Huanshan was not to blame. Their main research direction was superconducting materials.
In terms of research on anti-gravity materials, the several materials they already have are sufficient.
For example, the material can support the creation of more than 75% of the conventional anti-gravity field strength, and can also support the creation of more than 93% of the lateral anti-gravity field.
Of course they also want to develop new anti-gravity materials, but even if they develop them, it will be difficult to surpass them in performance.
For first-order iron and first-order lithium, they only replace conventional iron and create corresponding superconducting materials.
This already requires a lot of work.
Wang Hao thought about it and said, "Well, you set up a new experimental group, and I want to study new antigravity materials containing first-order iron."
Deng Huanshan said in surprise, "Academician Wang, do you want to personally lead the research team?"
"Yes, it's faster..."
"Very good!"
Deng Huanshan was immediately pleasantly surprised, and he couldn't wait any longer.
In recent years, the Superconducting Materials Research Center has made many achievements, but compared with the original, it is difficult to say that there is a "qualitative breakthrough", it is just a slight increase in the superconducting critical temperature.
To this day, he still clearly remembers working on superconducting materials with Wang Hao when the laboratory was established.
That was an ‘amazingly rapid breakthrough’!
The critical temperature of the iron-based superconducting material they created started from 73K and quickly reached 131K. The improvement speed is extremely fast and astonishing.
When Wang Hao stopped participating in relevant work, the research returned to its normal "slow pace".
After you have the feeling of "rapid breakthrough", and then you can do research slowly at a "turtle speed" and achieve results bit by bit, the feeling will naturally be completely different.
Deng Huanshan was suddenly filled with surprise and excitement, and immediately went down to arrange the establishment of a new experimental team.
Wang Hao went to his office.
He is the deputy director of the Superconducting Materials Research Center and has an office of his own. Even though he rarely comes to work here, someone is always cleaning and organizing the office.
After arriving at the office, he opened the computer to view the information, and also opened the system's task interface and established a new research task.
【Task 3】
[Research project name: Research and manufacture anti-gravity materials containing first-order elements (difficulty: a).]
[Inspiration value: 0.]
"The difficulty level is only A?"
"really!"
"With sufficient basic support, antigravity material research is not difficult..."
…
Deng Huanshan is very efficient.
In the afternoon, he summoned more than thirty people to the conference room and explained that he would establish a temporary experimental group to study a special superconducting material.
Because of possible confidentiality issues, he did not mention 'anti-gravity'.
When they learned that Wang Hao was personally leading the research, the technicians who came to the meeting were very excited. Some of them were old people in the laboratory and had originally studied superconducting materials with Wang Hao.
They had the same feeling as Deng Huanshan, and they couldn't help but recall their past "rapid breakthroughs".
Others are also looking forward to it.
At the same time, some people are also very puzzled. They understand that luck plays a large role in the research of superconducting materials.
Although the field of superconductivity is supported by semi-topological theory, the theory only gives one direction. When it comes to materials research, the most is a 'three-element combination'. However, the superconducting materials they study are very complex compounds, and even
It is a composite material formed from a variety of compounds.
The so-called ‘three-element combination’ and ‘two-element combination’ are, at most, just giving a direction.
If you want to develop new superconducting materials, theoretical foundation, experience, and luck are all indispensable, and luck may be more important than the first two.
This is true for most materials research.
With the support of theoretical foundation and experience, you need luck to achieve results. With good luck, creating a new material will have superconducting properties.
If you are unlucky, no matter how hard you try, the material you create will not have superconducting properties.
To put it simply, the research on superconducting materials has a clear direction, but there is no fixed method. In many cases, luck can play a big role.
Even if Academician Wang personally leads the research team, can he definitely develop new superconducting materials?
…
soon.
The new experimental group was determined, with a total of twenty-seven people, divided into five groups. Later, Wang Hao appeared in the conference room and briefly explained the research content.
Then comes the next step.
Wang Hao asked each group to prepare a report and write down their ideas for the direction of the experiment. The first step in the research was naturally to brainstorm.
Then he waited for three days.
On the afternoon of the third day, Wang Hao came to the Superconducting Materials Research Center again, asked each group to hand in their reports, and then called everyone for a meeting.
He carefully read every report and made comments one by one.
The technical staff who came to the meeting were all surprised.
At the same time, many people also lamented Wang Hao's seriousness in his work, "I originally thought that after submitting the report, it would be great if Academician Wang could take a few glances at it, but I didn't expect that he would comment on it at the meeting..."
To be continued...