Liu Yunli guessed correctly.
Wang Hao is indeed confident in the verification of DC anti-gravity properties, and he predicts that there will be materials that meet the requirements of DC anti-gravity.
This is not a flat estimate, but a conclusion based on experience.
So far, only two high-voltage hybrid materials have been used in the research of DC antigravity. They seem to be completely unrelated to metallic superconducting materials, but some correlation can still be found.
For example, both high-pressure hybrid materials have AC superconducting antigravity properties.
This leads to a loose conclusion that materials with DC anti-gravity properties must have AC superconducting anti-gravity properties.
From the study of the anti-gravity properties of first-order iron superconducting materials, it can also be found that whether it can stimulate anti-gravity properties before reaching a 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 are still obtained that are not rigorous and may be of great help to experiments.
For example, the covalent bond of first-order iron.
There are three types of chemical bond links between compound atoms, one is ionic bond, the other is covalent bond, and the last one is metallic bond.
Ionic bonds are formed by electron transfer between atoms, forming positive and negative ions, and are formed by electrostatic interactions.
Metallic bonds, which mainly appear in metals, are composed of electrostatic attraction between free electrons and metal ions arranged in a crystal lattice.
A covalent bond is when two or more atoms use their outer electrons together to reach a state of electron saturation under ideal circumstances, thus forming a relatively stable chemical structure.
The essence of a covalent bond is the electrical interaction between the electrons and the two nuclei that appear with a high probability after the atomic orbitals overlap.
By comparing the data from the anti-gravity characteristic experiment and comparing the elemental composition analysis of the compound, we can draw a conclusion--
The more covalent bonds formed by first-order iron, the more likely it is that an antigravity field will be excited at a higher temperature than the critical temperature.
This conclusion is very imprecise.
However, Wang Hao can determine that materials containing first-order iron excite an antigravity field and are related to covalent bonds through 'correct feedback'.
Of course, there are many factors related to antigravity properties.
Covalent bonds are just one of them.
Among various related factors, it is also difficult to judge the importance of covalent bonds. Because of this, Wang Hao's statement is "maybe one or two."
He is still looking forward to the experiment very much.
The next step is constant experimental preparations. Verifying the DC anti-gravity characteristics of each material is a very complicated task.
DC antigravity is much more complicated than AC superconducting antigravity.
If the material layout design difficulty of AC superconducting antigravity is rated as ‘100’, then the difficulty of related work of DC antigravity will reach ‘300, 400’, or even more.
Experiment preparation is time-consuming.
After spending more than two weeks of hard work, they verified the most anticipated FCW-031. In the AC superconducting antigravity experiment, the antigravity field strength excited by FCW-031 reached 7%, which is among several materials.
The median value is the highest.
Unfortunately.
The final experimental results show that FCW-031 does not have DC anti-gravity characteristics.
When all the data analysis work was completed and Wang Hao confirmed the results, a tone of disappointment came from the conference room.
"FCW-031 does not have DC anti-gravity characteristics? It is the most promising one."
"Failure is normal..."
"But it's still very depressing because we have 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, and this is just 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 also contains first-order iron and first-order lithium. It is very special and may have DC anti-gravity properties."
FCW-025 contains first-order iron and first-order lithium, and is a metal compound with a very complex composition.
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 detect DC anti-gravity properties...
"Is that possible?"
"Academician Wang said he would give it a try. I think there may be hope."
"Material No. 25 is indeed special. It has the most complex element composition and at the same time, the intensity of the anti-gravity field it stimulates is the lowest."
"First the highest number is 31, then the lowest number is 25. Academician Wang arranges experiments in a regular manner."
"Just follow along..."
…
While Wang Hao was focusing on verifying material properties, public opinion at home and abroad was already boiling over the new findings of the annihilation force field experimental team.
"Annihilation Physics and Theory" has released a new issue.
The first article was titled "New Discovery of Upgraded Materials: First-Order Carbon Element", which quickly attracted the attention of scholars in all journals.
Soon the news spread out of academia.
Many media outlets that pay attention to the research on strong annihilation force fields have reported on the discovery of first-order carbon. Several of them are extremely influential international media outlets, and each of their headlines is very eye-catching -
"Wang Hao's team discovered first-order carbon, and the third element is actually a non-metal!"
"The most important upgrade element is discovered!"
"The way out for this year's biggest physics achievement, 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 technological breakthroughs and development!"
"level one……"
The public opinion this time is much higher than when first-order lithium was discovered, mainly because the carbon element is so important.
The media conducted a large number of reports and conducted a large number of comments and analyses.
Carbon is one of the most important elements.
For known life systems, carbon element is indispensable. Without carbon element, life cannot exist, and life on earth is also called carbon-based life.
This chapter is not finished yet, please click on the next page to continue reading the exciting content! Some media analysis reports start from the importance of carbon to life. Their analysis is very interesting.
They believe that the discovery of first-order carbon elements may sublimate the essence of human life.
"It is the most important component of life."
"If all the ordinary carbon elements in the human body are replaced with primary carbon elements, will the essence of human life be improved?"
"First-order elements have a higher 'level' than ordinary elements..."
"..."
This statement has no scientific basis, but it has aroused widespread heated discussion in public opinion. After all, having no scientific basis does not mean it is wrong.
Many people have discussed "first-order carbon can sublimate human beings", "If all carbon becomes first-order carbon, I will definitely become stronger."
"What's so great about being strong? You can do it by exercising. I think that first-order carbon can make me become a superman and have some special abilities, such as emitting light waves."
"It may also be to become an immortal or a god."
"I think the most likely possibility is that after your body has a large amount of first-order carbon, you will soon develop cancer..."
"First-order carbon is 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 analyze it from a scientific perspective and popularize some knowledge about carbon elements so that more people can understand the application fields of first-order carbon.
Simply put, it's very broad.
To be continued...