Parsons' idea is not unique.

After the end of the Chinese Mathematicians Conference, many media around the world reported on it.

The report elaborates on Wang Hao's new achievement, that is, to describe the mode of action of annihilation force by constructing the microscopic topological morphology of a single element conductor.

This is the first time that the relevant mathematical framework has been completed since the emergence of the annihilation theory.

At the same time, Wang Hao also used the constructed mathematical content to calculate that the "missing data" fluctuations in the particle collision experiment are equivalent to the second prediction of the experiment.

Many scholars immediately became interested in the theory of annihilation.

Some of them share Parsons's idea to get more funding, while others are very interested in finding a new direction to study.

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

Scientists are human beings and have their own lives.

Most researchers do research not all for hobbies, especially some young researchers, who will choose projects in their field of expertise that are easier to apply for funding.

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

In addition, many scholars also see the potential of annihilation theory, and a new field with potential becomes very attractive because it is easier for the new field to produce results.

That's what the original string theory was.

String theory was first developed to explain the large number of mesons found in particle collision experiments, and the initiator of the theory was the Italian physicist Gabriel Veniziano.

In the course of particle collision experiments, physicists discovered that there is a very simple linear relationship between the spin and weight of mesons. @精华\/Shuge Error-free Debut~~

Gabriel Vigniziano "guessed" an equation based on the results of the experiment.

Later, other physicists, who explained Viniciano's equations, assumed that there was a fundamental unit smaller than the particle, the string, and calculated the interaction between the strings to reconstruct Viniciano's mathematical formula.

This was the beginning of string theory.

At the end of the sixties, string theory was undoubtedly a completely new theory, and the theory was soon expanded to include open strings, closed strings, and "superstrings", all of which were mainly used to describe a class of particles called "bosons".

Later, in the late 80s, Nevo and Ramon contributed to the extension of string theory to fermions, or superstring theory.

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

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

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

In the first 20 or 30 years, many mathematicians and physicists participated in the shaping of string theory, so that the theory was rapidly improved step by step, and they also had achievements one by one.

In the last two decades, there has been little development in string theory.

Even Edward Witten, who is considered the first person in string theory, did not have too many outstanding achievements in the perfection of string theory.

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

The theory of annihilation is the most recent.

Compared with chord theory, the annihilation theory has a great advantage, that is, through theoretical research, experimental verification, and even calculating the results of particle collisions, it shows that the annihilation force is likely to exist, and the annihilation theory is also likely to be correct.

To study a correct theory will certainly have great potential.

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

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

After leaving the city and returning to Holand, Didier Mayor accepted. (This chapter is not finished!) )

Chapter 235: Not a Replica, but a Transcendence!

In an interview with the reporter, he talked about what happened at the Chinese Mathematicians Conference, expressed his admiration for Wang Hao and Paul Phil-Jones, and then 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 achieve a grand unification of physical systems."

"The main purpose of the annihilation theory is to introduce gravity into the microscopic physical system, and annihilation is the microscopic manifestation of gravity. A mass-space interaction has been added to the theory, but there is no more explanation. ”

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

"As for the conflict in the underlying definitions of chord theory, I don't think that's accurate. First of all, string theory is only a physical explanation, and it is necessary to prove the correctness of string theory first, and then it can be used to explain its relationship with annihilation theory by "conflict". ”

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

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

String theory, it's hard to say.

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

In the microscopic physical system, string theory also plays a great role in solving some physical problems, such as black holes, early universe, condensed matter physics, etc., all of which have the application of string theory explanation.

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

Therefore, it does not matter whether the two theories conflict or not.

Many physicists understand both theories in this way, which makes some string theory scholars reluctantly accept it.

Paul Phil-Jones is certainly not included in it.

Paul Phil-Jones's worldview, in which what is right is right and what is wrong is wrong, cannot accept two theories that define conflict together.

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

"The theory of annihilation, there must be something problematic! I'll definitely find out!"

Paul Phil-Jones is very serious.

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

At the same time.

Wang Hao had already returned to Xihai University, and he only waited for two days to get to Birkal.

Birkar is also interested in follow-up research.

In fact, Bill Carr had long wanted to come to Seohai University, and he found that he was doing research at Mizuki University without any progress at all.

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

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

Wang Hao, Lin Bohan and Bill Carr, the trio got back together, and they immediately entered into a focused discussion and research.

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

"Previously, we wanted to use one equation or several equations to represent the microscopic patterns. But when I think about it, it's not practical at all. ”

The other two nodded their heads.

Wang Hao continued, "We can analyze the sub-modules, and give the side definitions, and use the definitions to cooperate with the equations to realize the semi-topological architecture. ”

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 not possible to cover the solution of one equation or several equations.

After having a specific direction, they began to study from the simplest "two elements" and "three elements", and later found that the logic was still too complicated, Wang Hao found another person to join the research group.

Luo Dayong.

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

Threesome, turned into a foursome.

。 (This chapter is not finished!) )

Chapter 235: Not a Replica, but a Transcendence!

Wang Hao served as the team leader.

Lin Bohan is responsible for topology problems; Birkar is responsible for problems with algebraic geometry; Luo Dayong will give advice on mathematical logic issues.

Their research base is located directly in the director's office of the Mason Number Lab.

When the research was too engrossed, they even began to forget to sleep and eat, and as a result, they had to ask others to help deliver food, so Zhang Zhiqiang and Zhu Ping, who were relatively idle, took over the work related to food delivery.

Zhang Zhiqiang was very depressed. Initial Update@

When Wang Hao, Lin Bohan and Bill Carr studied together, he didn't have any special feelings, because the other party was studying professional mathematical problems.

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

Zhang Zhiqiang has always felt that he and Luo Dayong are "on the same footing" in the office of the comprehensive building, but now he finds that there are still differences, and the differences are very big.

Luo Dayong can join Wang Hao's research group, and he can only be responsible for delivering food with Zhu Ping.

"Ah~~"

After delivering the food to the office again, and then being pushed open and left by a group of people in ignorance, Zhang Zhiqiang sighed fiercely at Zhu Ping, "Why did I fall to the point of delivering food?" ”

"What's wrong with the food delivery?"

Zhu Ping was suddenly dissatisfied, "Send food to our family, I'm willing!"

"I didn't mean that!"

Zhang Zhiqiang suddenly became even more depressed, he leaned over to Zhu Ping and whispered, "I mean, Zhu Ping, do you think I can still study mathematics from now on?" ”

"Why?"

"I also want to join Wang Hao's research group...... Zhang Zhiqiang feels that joining Wang Hao's research group and saying it is a very face-saving thing.

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

He found himself unable to keep up.

It felt like he was about to be eliminated by the times, but in fact, he was only just over thirty-five years old.

So he was very envious of Luo Dayong.

Zhu Ping looked Zhang Zhiqiang up and down, pinched his chin with his thumb and forefinger to think, and nodded, "Your idea is quite good, but there is a little bit of it." ”

"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 looked in a mirror, and found that there was a place on the top of his head, and a large piece of scalp could be clearly seen.

He took a deep breath and stopped thinking about the math.

Mathematics?

Hair is important!

……

Wang Hao's research group is progressing very well.

Because of the shaping of some small modules, Wang Hao also found the physics laboratory and asked the physics laboratory to do an AC gravity experiment to verify it.

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

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

Although it has entered the validation stage of research, the research still lacks a key condition - the problem of microscopic morphological gaps.

"We have to find this gap, otherwise the research will be imperfect."

"I believe that the microscopic form of any elemental composition cannot be perfect, and since it cannot be perfect, there will be gaps."

"There will be big and small gaps, there will be many directions, not necessarily one gap, maybe many gaps, at the same time, the microscopic gaps will also be reflected in the experiment, we must complete the expression of the gap through theory."

"That's the most important part of the experiment!"

……

In the gap demonstration part of the microscopic form, the progress of the research group was not smooth, because there was no concrete data, and it was difficult to draw conclusions based on imagination alone.

They discussed it together for two weeks, but they only completed a part of the "illusion form".

If these hypothetical patterns are verified, it will definitely cost a lot of money and will not necessarily have results.

"Massive", the funds can easily reach a few. (This chapter is not finished!) )

Chapter 235: Not a Replica, but a Transcendence!

billion, or even more.

Again, the research stopped.

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

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

It's only three points short of inspiration, but it can't go up. Initial Update@

The "gap" is the key.

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

"What's the news?"

"The latest results report, Science magazine!" He Yi explained, "The superconductivity research group at the University of Chicago has discovered the problem you mentioned! ”

Wang Hao was stunned for a moment, and couldn't help but stand up and said in surprise, "You mean, the superconducting pre-temperature is found to create a higher AC gravity field strength?" ”

"Yes!" He Yi nodded vigorously.

Wang Hao checked the content of the latest issue of Science magazine and saw the relevant news.

The superconductivity experiment group at the University of Chicago discovered a mixture of carbon, hydrogen, and sulfur, and achieved room-temperature superconductivity with a superconducting transition temperature of 15 degrees Celsius when pressurized to 260 GPa.

What's more, they observed an extreme of 18% of the AC gravity field strength at 20 degrees Celsius.

At the same time, at a 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 intensity of the mixed gas pressurization is too high, 260GPa, that is, 2.6 million times the atmospheric pressure, is not at all conventionally applicable.

In addition, the mixed gas is not a normal superconducting material, and the maximum current extreme value that can be withstood is too low, and it is far from catching up with ordinary conductors, so there is no possibility of application.

The latter is the most important.

When it is greater than the superconducting transition temperature of 5 degrees Celsius, the extreme value of the AC gravity field strength is observed, which is definitely a great discovery in the study of AC gravity.

Sauls Brown, head of the Superconductivity Experiment at the University of Chicago, said excitedly in an interview, "This discovery is very meaningful." ”

"As long as we study the principle of its emergence, I believe that there will be very significant progress in exploring the anti-gravity force and the superconducting mechanism."

This new discovery has shocked the physics community.

Many of the Amriken media have also been reveled in this because they seem to be in a backward position in the field of superconductivity mechanism research.

The law of superconductivity was studied by Wang Hao.

Wang's geometry has been widely studied by the mathematical and physical communities, and hopes to be extended to a higher level to cover complex element combinations in order to analyze the superconductivity mechanism.

This is the main direction of superconductivity mechanism research, all from Wang Hao, or it can be said, all from the Chinese research team.

With the new discoveries made by the University of Chicago's superconductivity experiment, they may be able to catch up with China's research progress.

The study of alternating gravity combined with superconductivity has become a direction that has attracted worldwide attention.

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

The impact of this discovery is naturally significant.

Only the next day, Zhou Minhua, deputy director of the Science and Industry Bureau, and Wu Hui, academician of the Superconductivity Office of the Science Foundation, called to ask Wang Hao, and then immediately took a plane to Xihai University.

The Bureau of Science and Industry and the Science Foundation are both the parent departments for the exchange of gravity research projects.

Zhou Minhua and Wu Hui are concerned about the same question, that is, "will the new discovery of the University of Chicago promote Ameriken's research on the exchange gravity and superconductivity mechanism to surpass the domestic surpassing".

Zhou Minhua was even more anxious, and after she saw Wang Hao, she couldn't help but ask, "Professor Wang, will this new discovery allow them to make other new discoveries and surpass us?"

"Of course not."

Wang Hao chuckled indifferently, "Director Zhou, you're worrying too much." ”

"Why?"

Wu Hui asked with some confusion, "The material has not yet entered the superconducting state, but it has been checked." (This chapter is not finished!) )

Chapter 235: Not a Replica, but a Transcendence!

Measuring a higher AC gravitational field strength should be a surprising discovery, right?"

Wang Hao pursed his lips and thought for a moment, "If you are still worried, it is very simple. @精华\/Shuge*First Update~~"

"So, I'll write a mixture of gases. If you let the other experimental groups do it according to the ratio, you should be able to replicate their experiments. ”

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

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Chapter 235: Not a Replica, but a Transcendence!