From University Lecturer to Chief Academician

The interim meeting organized by the Science Foundation mainly discussed the content of leading the establishment of the International Organization for Superconducting Technology.

International organizations will play a very important role in a wide-ranging cutting-edge technology, and a dominant position in an international organization can bring a series of benefits.

The latest theory of superconductivity was proposed in China, and the country will naturally consider taking the lead in establishing an international organization, and the meeting is to discuss specific content.

They have drawn up a charter, which mainly includes several aspects.

The first is the information sharing of theoretical research.

For example, a team has studied the superconducting critical temperature corresponding to a certain combination of two elements.

In order not to waste scientific resources, other teams can give up research and directly use the results of other teams.

In the study of dual elements, it is impossible for any team to cover all the combinations, so information sharing is naturally very important.

Other directions of superconductivity theory research can also be shared, such as the conflict of some element combinations, because it is likely to involve applied research, and some institutions may keep the results secret.

If all institutions do this, the development of superconducting technology will definitely be greatly limited.

In addition, the subsequent development and application of superconducting materials will also involve many complicated issues.

For example, if a certain institution has developed a superconducting material that can be used in industrial production, because materials generally do not have patents at all, many institutions will definitely carry out reverse engineering.

So how to protect the patent in the process? Or random reverse engineering will definitely make the market very confusing.

The superconducting international organization can play a coordinating role in it.

etc.

Superconducting international organizations can involve many fields, and if they occupy a dominant position in the organization, they can develop the rule-making in a direction that is beneficial to them.

In terms of the current international situation, in the field of superconducting technology that can allow human science and technology to take off, it is very difficult, or even impossible, for the country to take the lead, because many countries will directly give up joining the organization.

These are things that need to be discussed.

Many people believe that superconducting technology will soon usher in rapid development, and the top level must be state-to-state negotiations, while the Science Foundation is leading the relationship between institutions.

The relationship between institutions and institutions is equivalent to contact in the academic field, which will not involve too complicated issues, and the organization of the academic field also needs to discuss some issues such as rules.

That's what the meeting is for.

This kind of rule-making and discussion-related conferences has nothing to do with most scholars, and they can only provide technical and theoretical reference opinions.

Wang Hao didn't say a word the whole time, and just listened to the content of the meeting.

After the meeting ended, he was surrounded by several scholars, including Wang Chenglin and Du Jianwei. The two found Wang Hao to talk about the connection between semi-topological theory and superconducting condensed matter physics mechanism.

Wang Hao also patiently expressed his opinion, "My idea is to study from the direction of annihilation theory."

"I have been studying the theory of annihilation. The mathematical framework is very closely related to the theory of condensed matter physics, and it is still from the perspective of microscopic particles."

"If a relevant mathematical system can be constructed, I think it will be possible..."

Wang Hao continued talking for a long time. He was explaining very seriously, and he also reminded, "I will do this research when I go back. It involves the construction of annihilation theory, which is very important to my own research."

This is a reminder.

Wang Hao could tell that Wang Chenglin and Du Jianwei were very interested in the direction he said, but he felt that he would finish the research soon, so he simply said it directly and clearly to make the two of them 'give up' on the research.

Wang Chenglin and Du Jianwei could also hear Wang Hao's meaning, but their thoughts were completely different from Wang Hao's.

Of course they recognized Wang Hao's research ability.

If they are doing the same research, they have no confidence that they can be faster than Wang Hao, and they may even choose to give up directly.

But they believe that their research direction is different from that of Wang Hao.

Wang Hao started his research from the perspective of annihilation theory, that is, from the direction of semi-topology, to study the connection with condensed matter physics; they are all specialized in the research of superconducting condensed matter physics, starting from the direction of superconducting condensed matter physics, and finally To contact the theory of semi-topology.

It's like digging a cave. Wang Hao started digging from the east side of the cave, and they started from the west side.

It is impossible to connect the caves directly, it must be a process.

In the process of Unicom, there will definitely be results one by one, and they can naturally pursue these results after doing relevant research.

After hearing Wang Hao's words, the two immediately had a lot of expectations.

After leaving intact, they couldn't help looking forward to it even more after thinking about it, and then looked at each other with smiles on their faces.

At the same time, fierce sparks appeared in the air again.

...

Two days later, the International Conference on Superconducting Materials and Mechanisms was officially held.

The meeting was supported by the Academy of Sciences, the Natural Science Foundation, and the International Federation for Applied Superconducting Physics, and was co-hosted by the Condensed Matter Physics Laboratory and the Superconducting National Laboratory at the International Conference Center in Sudong.

In the morning, there were already many people at the venue.

These include some internationally renowned superconducting experts, some mathematicians related to algebraic geometry, some theoretical physicists, and professional teams sent by major institutions, etc.

The venue where Wang Hao came has become the focus of attention since he was surrounded by a group of scholars, constantly talking about research related to semi-topology.

The second person who received attention was Birkar, who came with the Capital University team.

Almost all scholars in the field of algebraic geometry hope to discuss the application of algebraic geometry in the study of superconducting mechanism with Birkar.

The latest research results of Wang Hao's team have greatly enhanced the status of algebraic geometry.

Algebraic geometry seems to have changed from the study of pure mathematics to the study of applied mathematics.

Scholars in various fields of algebraic geometry are naturally worth doubled. Some doctoral students in the field of algebraic geometry often worry about job problems, but now they are not worried at all. Many institutions have contacted them early and found jobs in advance.

From this we can know how scarce algebraic geometry talents are.

The main problem in the field of algebraic geometry is that graduate students are not accessible at all, and only doctoral students can say that they have achieved success in their studies. The threshold of the field is very high.

This is one of the reasons why algebraic geometry talents are scarce.

The other key figures are Luo Dayong and Lin Bohan, and their respective researches have also attracted a lot of attention.

Wang Hao also met some international and domestic scholars in the process of communicating with others.

Most scholars greeted Wang Hao with smiles, but some scholars were different.

For example, some experts in the field of condensed matter physics would be happy if they saw Wang Hao grinning. The one who impressed Wang Hao was Thales Parisi, a famous theoretical physicist.

When Thales Parisi saw Wang Hao, he just smiled at him, shook hands symbolically, and then walked away without paying attention.

That expression can be interpreted as a complete disdain to communicate with Wang Hao.

Wang Hao just pursed his lips lightly. Of course he understood why those international experts in condensed matter physics didn't have a good face when they saw him.

Probably the reason is that their jobs are about to be smashed.

Where there are disciplines rise, there are disciplines that decline.

Conventional superconducting condensed matter physics research is one of the declining disciplines, because their research seems to have lost its meaning.

But in fact, Wang Hao does not think that the study of superconducting condensed matter physics has lost its meaning, just because he linked the issue of superconducting critical temperature based on elemental composition.

However, the research on superconducting condensed matter physics can continue to provide support for the theoretical mechanism of superconducting in the microscopic field.

The theory of semi-topology still has limitations, for example, it cannot demonstrate the composition of too complex elements.

If it is to conduct research on superconducting applied materials, for example, to study superconducting materials at room temperature, the theory of semi-topology is insufficient.

Either it is by chance to develop room temperature superconducting materials; or it is necessary to continue to perfect the theoretical mechanism of superconductivity.

Wang Hao is well aware that the research on semi-topology has reached its limit. It is impossible for him to completely decipher the mystery of superconductivity by relying only on the demonstration of microscopic morphology. If further research is carried out, it will definitely be related to the theoretical content of superconducting condensed matter physics.

The physics community probably hasn't realized this yet, which makes superconducting condensate physics experts seem to be out of a job.

Of course, it is also because it has not developed to that point.

At present, there are no superconducting materials with a critical temperature above 100k that can be applied to industry, so naturally there is no need to consider any room temperature superconducting materials.

...

When Wang Hao was talking about semi-topological research with others, there was an "acquaintance" from Caltech who was sitting and watching from a distance, his eyes were a little complicated.

It was Paul Phil Jones.

Paul Phil-Jones is here again, but the purpose is not to deny the annihilation theory, but hope to hear something about the annihilation theory.

After returning to Caltech, Paul Phil-Jones began to seriously study the theory of annihilation, hoping to find out the theoretical problems with his own research.

After a period of time, he didn't find any problems, but he made some achievements in the research of annihilation theory.

For example, he constructed some mathematical content related to annihilation theory and quantum physics.

That didn't excite Paul Phil Jones.

After completing those studies, he realized that he seemed to 'help' the annihilation theory, and immediately tore up all the content. For a while, his state was even a little crazy.

Many colleagues are afraid to contact Paul Phil-Jones, because they feel that Paul Phil-Jones' state is not right, like a lunatic, occasionally talking to himself, and even smashing things in the office .

Paul Phil-Jones feels very painful inside. He has always believed in string theory, but now he finds that he likes to study annihilation theory.

In fact, it is also very normal. String theory has been studied for decades, and many mathematical frameworks have been perfected. If you think about further research, the difficulty becomes very high.

Annihilation theory is different.

The theory of annihilation is a brand new content, and there is only a very simple mathematical structure for the time being.

This is like a newly discovered small river. No one knows how many fish and what kind of fish there are in the river. A fisherman who likes to fish catches many new kinds of fish at one go on the bank, and there will naturally be a kind of Excited feeling.

Paul Phil Jones felt this feeling, but he was very ashamed of how he felt. He felt that he had betrayed string theory and become a shameful traitor like Ridley.

When Paul Phil-Jones came to Sudong, he still hoped to hear some annihilation theory content. The reason he gave himself was, "If you know some new content, you may find out the problem."

Seeing Wang Hao surrounded by him now, Paul Phil-Jones reminded himself again, "I'm just looking for problems, not hoping to hear some new theoretical content..."

"Yes, I'm just here to find a problem!"

"Only by understanding the theory better can we find out the problem!"

"I am not Ridley, and I will never betray string theory!"

...

The meeting officially begins.

There is no award-giving process for professional fields related to superconductivity.

The opening ceremony was just a summary of the achievements in recent years, emphasizing the latest research of Wang Hao and his team, looking forward to the take-off of superconducting technology in the future, and then the meeting entered the part of academic exchanges. The scholars who were invited to participate in the meeting , to do research and work reports respectively.

The conference received more than 200 papers, and there are a lot of research and work reports to be done.

On the first day, all the short reports were arranged. Some work reports were only 20 minutes long, and the new achievement reports were relatively longer, generally no more than 40 minutes.

Wang Hao has been listening patiently.

The content of the conference on the theoretical mechanism of superconductivity is related to the direction of conventional condensed matter physics, because the demonstration direction of the annihilation theory has been found, and the inspiration value of the task is also continuously increasing.

In one day, the inspiration value has increased to 30 points.

The next day was Wang Hao's report, or the report of Wang Hao's team. The team had a total of four reports.

The part that Wang Hao is doing is "the relationship between elemental composition and microscopic geometric structure".

The other three have made reports on their achievements in their respective fields.

The second one that has received attention is Birkar's research on algebraic geometry. For the inverse composition method of high-dimensional node graphs, the research can be said to be very prominent, even reaching the level of half Fields.

Wang Hao's report was scheduled for nine o'clock in the morning. When he walked to the stage, he noticed a lot of unfriendly eyes.

Those are experts in condensed matter physics from the field of superconductivity.

This meeting was a meeting on the mechanism of superconductivity. Half of the people who attended were experts in condensed matter physics. Fortunately, domestic experts in related fields were not very hostile to him, but foreign scholars were different.

Many of them feel that their jobs have been smashed, and it is normal for some projects to be blocked.

Although they are still experts in condensed matter physics in the field of superconductivity, they feel that the importance of research and the degree of attention have been greatly reduced.

This makes them very dissatisfied.

In addition, they also have similar ideas to Wang Chenglin.

The research on the theoretical mechanism of superconductivity can be traced back a hundred years. During this period, five superconductivity researches won the Nobel Prize in Physics alone, and ten scholars won the Nobel Prize in Physics.

So many heavyweight studies have formed a research discipline of basic logic, and because of Wang Hao's semi-topological research, the overall status has dropped greatly.

Does the research related to condensed matter physics in the field of superconductivity become meaningless?

Of course, Wang Hao would not answer this question. Faced with a lot of unfriendly eyes, he just came to the stage and gave a report indifferently.

His report was about the relationship between elemental composition and microscopic geometric structure, which was demonstrated from a mathematical point of view.

Most of the content of the report is analysis and calculation, based on Wang's geometry of single-element semi-topological form, combined with a part of the mathematical structure of annihilation theory, and finally demonstrated the relationship between microscopic geometry and element composition.

From the beginning to the end of the explanation, it took about an hour and a half.

Because most of the involvement is definition and construction, and there is no complicated logical process, it is relatively understandable.

In fact, the hard part lies in other people's research.

Including the theoretical combing of complex geometry, the relationship between semi-topology and topology, as well as the inversion and composition of high-dimensional node geometry, involving the contents of the three disciplines, all of which are very advanced research.

On the contrary, the report made by Wang Hao is the simplest, most of which are definitions and calculations.

The definition, of course, does not need to be understood.

Whether these definitions are correct or not is related to whether the results are correct or not, as long as it is proved by experiments.

On the same day, four people gave reports separately, and scholars in various fields felt that they had gained a lot. It is almost impossible for them to understand all the content alone, and they can only find the content in their respective fields to understand.

On the third day, the academic report continued.

The report this morning was very unusual, because it was Thales Parisi who came to the stage to give the report. Parisi is a very famous theoretical physicist.

Although he has never won a Fields or a Nobel, Parisi is recognized as the scholar who has made the greatest contribution to the research on the theoretical mechanism of superconductivity in the past two decades, especially in the construction of the underlying logic of the theory.

His research is mainly to analyze the mechanism of superconductivity related to theoretical physics, and the analysis he made is difficult to prove, but it links a series of theoretical discoveries of superconductivity together.

This is like creating a new physical theory system, such as creating the content of string theory, which can unify mechanics.

The two are about the same.

Thales-Parisi is naturally considered a top figure in the field of superconducting theory, and the content of his report is the latest research on the structure of superconducting magnetic crystals.

This report has not received much attention, mainly because the content is still within the scope of superconducting condensed matter physics.

Now the physics of superconducting condensed matter has not received much attention, and some fruitful researches are still paid attention to, but the theoretical content is hardly paid attention to.

Thales-Parisi's reputation is there. Even if the content is not very attractive, many scholars go to listen to the report.

When Parisi actually explained the content, the scholars who came to listen suddenly felt that his eyes lit up. He was demonstrating superconducting magnetic crystals, but he was related to Wang Hao's microscopic morphology and geometry.

When the report was halfway through, many people already knew what Thales Parisi was talking about, and they couldn't help but look at Wang Hao.

Wang Hao also knew what Thales Parisi was talking about, or what the purpose was, but he was still listening very carefully, because he thought the content of Thales Parisi's research was very interesting.

Thales-Parisi's research can be simply understood as proving that the microscopic form in the conductor is the superconducting magnetic crystal. At the same time, he also used the demonstration of the superconducting magnetic crystal to deny the role of annihilation force.

"Putting several columns together, we can do a comparative analysis, and we can find that the magnetic crystal spin has the same effect as the microscopic morphological framework."

"The structure of magnetic crystals can also replace the role of microscopic morphology."

"So I think that the so-called AC gravity is formed by the rotation of superconducting magnetic crystals..."

Thales Parisi said he wanted to look at the audience, but he mainly looked at Wang Hao. He had a smile on his face, but his eyes were obviously provocative.

He did not deny Wang Hao's research results, and he knew very well that there was no way to deny Wang Hao's research results, because many institutions have done research on the superconducting critical temperature of dual elements, and they have confirmed the correctness of the results.

When a result can be verified by experiments, any refutation related to the theory will become very weak.

No matter how perfect the mathematical structure is, and how logical the analysis is, can it be verified by experiments?

If not, it is of course meaningless.

What he denies is the theory of annihilation!

To be precise, it is the annihilation force that plays a role in superconductivity!

Wang Hao's theory holds that the annihilation force squeezes the microscopic form to form the superconducting phenomenon, and at the same time, the special situation in which the microscopic form is squeezed forms the phenomenon of alternating gravity.

He believes that the microscopic form is the structure of magnetic crystals.

At the same time, he demonstrated that the magnetic crystal spin can also be involved in the "semi-topological theory", rather than the annihilation force.

This argument is tantamount to excluding the effect of annihilation force, directly refuting the annihilation theory.

When Thales-Parisi finished the report, the superconducting condensed matter physicists in the audience applauded warmly, they were really excited.

"Parisi is worthy of being a top theoretical physicist. He actually constructed a mathematical system of magnetic crystals, replacing the role of annihilation force!"

"Magnetic crystals are microscopic forms? I like the idea..."

"This is a negation of the theory of annihilation. It's so interesting. It's a brand new explanation. What would Wang Hao say?"

"Parisi's research has its own logic. Anyway, I didn't find the problem. This is the real principle, right?"

"What annihilation theory, nonsense!"

Although Thales-Parisi did not deny Wang Hao's research results, he directly denied the effect of annihilation force. To be precise, replacing the effect of annihilation force with another explanation is tantamount to a very powerful counterattack against Wang Hao .

If his research results are confirmed, then the status of research related to superconducting condensed matter physics will also be improved.

Many scholars even believe that after excluding the annihilation force, the bridge between semi-topological systems and superconducting condensed matter physics has been opened.

Wang Chenglin and Du Jianhua were stunned. Of course they understood what Parisi's research was, and they also believed that the system had been opened up.

so……

They chose the research direction, and it ended before it even started?

When Thales Parisi finished the report and was waiting for questions from the audience, everyone in the lecture hall looked at Wang Hao.

The theory of annihilation was put forward by Wang Hao. He also demonstrated the mathematical framework of the theory of annihilation by relying on the microscopic shape of a single element.

Now that the role of the annihilation force has been 'replaced', to a certain extent, it is tantamount to negating the annihilation theory. Naturally, Wang Hao wanted to say something.

So, how would he refute it?

Or……

He couldn't think of it for a while, and became speechless?