From University Lecturer to Chief Academician

Chapter 236 Not a remake, but a transcendence!

Parsons' idea is not unique.

After the Chinese Mathematicians Conference ended, many media around the world made reports.

The report details Wang Hao's new achievement, which is to describe the action mode of the annihilation force side by side by constructing the microscopic topological shape in the single-element conductor.

This is the first time that the relevant mathematical framework has been completed after the annihilation theory appeared.

At the same time, Wang Hao also used the constructed mathematical content to calculate that the "data missing" fluctuations in the particle collision experiment were tantamount to predicting the experiment for the second time.

Many scholars suddenly became interested in the theory of annihilation.

Some of them have the same idea as Parsons, in order to apply for more funding, while others are very interested and feel that they have found a new direction for research.

In fact, it is very normal to do research for funding.

Scientists are people too, and they all have their own lives.

Most researchers are not all interested in doing research, especially some young researchers, they will choose projects that are easier to apply for funding in their professional fields.

With funding, follow-up research can be carried out.

In addition, many scholars have also seen the potential of annihilation theory. A new field with potential will become very attractive, because new fields are more likely to produce results.

The original string theory was like this.

String theory first appeared to explain the large number of mesons found in particle collision experiments. The initiator of the theory was Italian physicist Gabriel Veneziano.

During particle collision experiments, physicists discovered that there is a very simple linear relationship between the spin and weight of mesons.

Gabriel Veniziano 'guessed' an equation based on experimental results.

Later, other physicists interpreted Veniciano's equations. They assumed the existence of a fundamental unit smaller than particles - strings. They calculated the interactions between strings to reconstruct Veniciano's mathematics. formula.

This was the beginning of string theory.

At the end of the 1960s, string theory was undoubtedly a brand-new theory, and the theory was soon expanded into open strings, closed strings and superstrings, which were mainly used to describe a class called "glass strings". dice" particles.

Later, in the late 1980s, Nevo and Ramon contributed to extending the coverage of string theory to fermions, that is, superstring theory.

Such a string theory can already explain all elementary particles including gravity, and has become a grand unified theory of physics.

Later, Edward Witten of Princeton University constructed a further M theory based on research, realizing the second revolution of string theory.

From the development history of string theory, it can be found that from the initial emergence of string theory to the perfection of the theory, the development speed is very, very fast.

In the first twenty or thirty years, many mathematicians and physicists participated in the shaping of string theory, allowing the theory to be rapidly improved step by step, and they also achieved results one by one.

In the last two decades, string theory has seen little development.

Occasionally there are some small achievements, and it is difficult to attract much attention. Even Edward Witten, who is considered the first person in string theory, has no outstanding achievements in the improvement of string theory.

There is no doubt that the study of string theory has reached a bottleneck.

Annihilation theory is the newest theory.

Compared with string theory, annihilation theory has a great advantage, that is, through theoretical research, experiments can be verified, and even the results of particle collisions can be calculated, which shows that the annihilation force is likely to exist, and annihilation theory is also very likely is correct.

Going to work on a correct theory certainly has enormous potential.

Of course, compared to string theory, the problem of annihilation theory is also obvious. It is not a unified theory and cannot explain complex particle problems.

The purpose of its emergence is only to introduce a microscopic force called "annihilation force", and some definitions and explanations of the theory seem to have nothing to do with the existing microscopic physical system.

After leaving Lingcheng and returning to Holan, Didier Mayor was interviewed by reporters. He talked about what happened at the Chinese Mathematicians Conference, and expressed admiration for Wang Hao and Paul Phil-Jones. , he explained the difference between string theory and annihilation theory, "the two are completely different."

"The goal of string theory is to explain all physics and realize the grand unification of physical systems."

"The main purpose of the annihilation theory is to introduce gravity into the microscopic physical system. The annihilation force is the microscopic manifestation of gravity. An interaction relationship between mass and space is added to the theory, but there is no further explanation."

"In my understanding, the annihilation theory is a supplement to the existing microscopic physical system."

"As for the conflict with the underlying definition of string theory, I don't think this statement is accurate. First of all, string theory is only a physical explanation, and the correctness of string theory must first be proved before we can use 'conflict' to explain its relationship with annihilation theory .”

As an experimental physicist, Didier-Mayor undoubtedly supports the theory of annihilation.

The reason is very simple, the annihilation theory can predict the experiment, and the existence of annihilation force is likely to be verified in the future.

String theory is hard to say.

If it is only from a theoretical point of view, the physics community can accept it, and it has always been the case in the field of microphysics. Whichever explanation is more reasonable will be used.

In the microscopic physical system, string theory also plays a very important role in solving some physical problems. For example, black holes, early universe, condensed matter physics, etc., all have the application of string theory explanation.

At the same time, the study of string theory has also promoted the development of pure mathematics research.

Therefore, whether the two theories conflict is not important to most scholars.

Many physicists have the same understanding of the two theories, and some scholars of string theory reluctantly accept it.

Which certainly does not include Paul Phil - Jones.

In Paul Phil-Jones' worldview, what is right is right and what is wrong is wrong. He cannot accept two theories that define conflicts together.

After returning to Caltech, Paul Phil-Jones regained his confidence, and he began to seriously study the theory of annihilation.

"The annihilation theory, there must be something wrong! I can definitely find it out!"

Paul Phil Jones is very serious.

Like Parsons, he traced back to the origin of the annihilation theory, studied the law of superconductivity, Wang's geometry, and microscopic topological processes, etc.

at the same time.

Wang Hao has already returned to Xihai University, and he only waited two days for Birkar.

Birkar is also very interested in follow-up research.

In fact, Birkar wanted to come to Xihai University for a long time, but he found that he was doing research at Shuimu University without any progress at all.

When he was researching with Wang Hao, he felt that his mind was full of inspiration, as if he had returned to the peak period of scientific research when he was in his thirties, but when he was doing research alone, he felt completely opposite.

In addition, he is also very interested in the study of microscopic morphology and semi-topology.

The trio of Wang Hao, Lin Bohan, and Birkar got together again, and they immediately entered into a focused discussion and research.

Wang Hao talked about his own thoughts, "We can give a side definition."

"Before we wanted to use one equation or several equations to express the microscopic shape. But after thinking about it carefully, this is not practical at all."

The other two listened and nodded.

Wang Hao continued, "We can analyze the sub-modules, and give the definition of the side, and use the definition to cooperate with the equation to realize the semi-topological framework."

To put it simply, you can't eat fat people in one go.

In the face of such a complex geometric system, it is absolutely impossible for one equation solution or several equations to cover and express it.

After they had a specific direction, they began to conduct research on the simplest "double elements" and "three elements". Later, they found that the logic was still too complicated, so Wang Hao found another person to join the research team.

Luo Dayong.

When studying complexity problems, it is definitely no problem to find Luo Dayong to deal with mathematical logic problems.

Threesomes, turned into foursomes.

Wang Hao served as the team leader.

Lin Bohan is in charge of topology; Birkar is in charge of algebraic geometry; Luo Dayong will give advice on mathematical logic.

Their research base is directly set up in the director's office of the Mason Number Laboratory.

When they were too involved in the research, they even started to forget to sleep and eat, and ended up asking other people to help deliver the meals, so Zhang Zhiqiang and Zhu Ping, who were relatively free, took over the work related to the meal delivery.

Zhang Zhiqiang was very depressed.

When Wang Hao, Lin Bohan, and Bill Carr were studying together, he didn't feel anything special, because the other party was studying professional mathematics problems.

Now that Luo Dayong joined in, he felt a little depressed.

Zhang Zhiqiang has always felt that he and Luo Dayong are of 'equal status' in the office of the complex building, but now he finds that there is still a difference, and the difference is very big.

Luo Dayong can join Wang Hao's research group, but he can only deliver meals with Zhu Ping.

"Oh~~"

After delivering the food to the office again, and being ignored by a group of people who opened the door and left, Zhang Zhiqiang sighed fiercely at Zhu Ping, "Why did I end up delivering food?"

"What happened to the food delivery?"

Zhu Ping was immediately dissatisfied, "I am willing to deliver food to our family's Dayong!"

"I did not mean that!"

Zhang Zhiqiang suddenly became more depressed. He leaned close to Zhu Ping and whispered, "I mean, Zhu Ping, do you think it's okay for me to study mathematics hard from now on?"

"Why?"

"I also want to join Wang Hao's research group..." Zhang Zhiqiang felt that joining Wang Hao's research group would be a very face-saving thing to say.

He has also done research with Wang Hao, and now it is not easy to even do projects together.

He found himself unable to keep up.

That kind of feeling is like 'about to be eliminated by the times', but in fact, he is only just over thirty-five years old.

So he envied Luo Dayong very much.

Zhu Ping looked Zhang Zhiqiang up and down, pinched his chin with his thumb and index finger and thought about it, nodded and said, "Your idea is quite good, but there is only one point."

"What?"

"You don't have enough hair." Zhu Ping silently shook her head and walked away.

Zhang Zhiqiang was stunned for a moment, and immediately found a mirror to take a look, and found a spot on the top of his head, where he could clearly see a large piece of scalp.

He took a deep breath and stopped thinking about any math problems.

math?

How can hair be important!

...

Wang Hao's research group is progressing very smoothly.

Because the shaping of some small modules has achieved certain results, Wang Hao also found a physics laboratory and asked the physics laboratory to do communication gravity experiments for verification.

Later, I found Liu Yunli from Factory 244 and asked their experimental team to verify it together.

Now the research group is mainly to shape the combination of two elements, and make a broader definition based on the experimental results, so as to cover all possible element combinations.

Although it has entered the verification stage of research, the research still lacks a key condition - the gap of microscopic morphology.

"We have to find this gap problem, otherwise the research is incomplete."

"I believe that the microscopic form of any element cannot be perfect. Since it cannot be perfect, there will be gaps."

"The gap can be big or small, and it can have many directions, not necessarily one gap, maybe many gaps. At the same time, the microscopic gap will also be reflected in the experiment. We must complete the expression of the gap through theory. .”

"This is the most important part of experimental verification!"

...

In the gap demonstration part of microscopic morphology, the progress of the research team is not smooth, because without specific data, it is difficult to draw conclusions only by imagination.

They discussed together for two weeks, and they only completed part of the 'false form'.

If all these hypothetical forms are verified one by one, it will definitely consume a lot of funds and there may not be any results.

'A large amount', the funds can easily reach hundreds of millions, or even more.

Research stopped again.

Bilkar returned to Capital University, and the others returned to work.

Wang Hao could only stop regretfully, looking at the value of 'Inspiration: 97', he felt very depressed.

It's only three points away from the inspiration point, but it can't go up.

The 'gap' is the key.

He Yi suddenly came to the office that day, and said to Wang Hao anxiously, "Have you seen the news?"

"what news?"

"Report on the latest results, "Science" magazine!" He Yi explained, "The superconductivity research team at the University of Chicago discovered the problem you mentioned!"

Wang Hao was stunned for a moment, and couldn't help but stood up and said in surprise, "You mean, the discovery of superconducting pre-temperature creates a stronger AC gravitational field?"

"Yes!" He Yi nodded vigorously.

When Wang Hao checked the latest issue of "Science" magazine, he saw the relevant news.

The superconducting experimental group at the University of Chicago discovered a mixed material of carbon, hydrogen, and sulfur. When pressurized to 260GPa, it achieved room temperature superconductivity with a superconducting transition temperature of 15 degrees Celsius.

More importantly, they observed that at 20 degrees Celsius, the strength of the AC gravity field reached an extreme value of 18%.

At the same time, at the superconducting transition temperature of 15 degrees Celsius, the strength of the AC gravity field is only 14%.

The former’s room-temperature superconductivity is actually not a big achievement, because the strength of the mixed gas pressurization is too high, 260GPa, which is 2.6 million times the atmospheric pressure, is not routinely applicable at all.

In addition, the mixed gas is not a normal superconducting material, and the maximum current limit it can withstand is too low, which is far behind ordinary conductors, and it is impossible to realize the application.

The latter is what matters.

At five degrees Celsius higher than the superconducting transition temperature, the extreme value of the AC gravity field strength was observed, which is definitely a great discovery in AC gravity research.

Saul Brown, the head of the superconducting experiment group at the University of Chicago, said excitedly in an interview, "This discovery is very meaningful."

"As long as the principle of its appearance is studied, I believe that there will be very significant progress in the two directions of exploring antigravity and superconducting mechanisms."

This new discovery shocked the physics community.

Many American media also reveled because of this, because in the field of superconducting mechanism research, they seem to be in a backward situation.

The law of superconductivity was developed by Wang Hao.

Wang's geometry has been widely studied by the mathematics and physics circles, and it is hoped that it can be extended to a higher level to cover complex element combinations in order to analyze the superconducting mechanism.

This is the main direction of superconducting mechanism research, all of which come from Wang Hao, or it can be said that they all come from Chinese research teams.

The superconducting experimental group at the University of Chicago has made new discoveries, and they may use this to catch up with China's research progress.

The study of AC gravity combined with superconducting mechanism has become a direction that has attracted worldwide attention.

When the new issue of "Science" magazine came out, it immediately attracted the attention of the whole world, and there were even many cross-border discussions, which attracted the attention of ordinary people.

The implications of this discovery are naturally enormous.

On the second day, Zhou Minhua, deputy director of the Science and Industry Bureau, and Wu Hui, academician of the Superconductivity Office of the Science Foundation, both called to inquire about Wang Hao, and then immediately flew to Xihai University.

Both the Bureau of Science and Technology and the Science Foundation are the higher-level departments of the Exchange Gravity Research Project.

Both Zhou Minhua and Wu Hui are concerned about the same question, that is, "Will the new discoveries of the University of Chicago promote Americon's research on exchange gravity and superconducting mechanism beyond domestic research."

Zhou Minhua was even more anxious. After seeing Wang Hao, she couldn't help asking, "Professor Wang, will this new discovery lead them to make other discoveries and surpass us?"

"of course not."

Wang Hao chuckled nonchalantly, "Director Zhou, you are worrying too much."

"Why?"

Wu Hui asked with some confusion, "The material has not yet entered the superconducting state, but it should be an amazing discovery to detect a higher AC gravitational field strength?"

Wang Hao pursed his lips, thought for a while and said, "If you are still worried, it's very simple."

"In this way, I will write a mixture ratio. You follow the ratio and let other experimental groups do it, and you should be able to reproduce their experiments."

After he finished speaking, he added, "It's not just a replica, it should be beyond!"

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