After many verifications, Wang Hao and others determined that "5 and 17' are prime pairs of nodes of the function, and then substituted other prime numbers to solve the equation transformed from the function, and then obtained another corresponding prime number.

This discovery is significant.

Until now, mathematics has not been able to find an equation that can determine the solution of prime numbers. Everyone realizes that a function may contain some kind of law for the occurrence of prime numbers.

They summarized the research and submitted the sorted paper to "New Advances in Mathematics", and then Wang Hao published public information on the Internet.

That's news in a meager release.

Wang Hao's meager account has tens of millions of followers, and any news he publishes can cause heated discussions, and the release of relevant research progress can attract the attention of countless media outlets.

When the news was actually released, it quickly attracted a lot of discussion.

The function that Wang Hao came up with was reported before, and he himself made a public explanation, and later released a personal reward, announcing that anyone who has a breakthrough in the study of the function will be given a high reward.

The prize money started at 100,000 yuan, and then slowly became 500,000 yuan.

It can also be seen from the increase in the amount of bonuses that Wang Hao attaches great importance to the study of functions, and it can also show how difficult the research of functions is.

Wang Hao was originally one of the world's top mathematicians, especially in the field of number theory and partial differential equations, and it is not an exaggeration to say that he was "the first person, because he proved Goldbach's conjecture and solved the NS equation problem, one of the seven major mathematical problems of the millennium."

For the current function research, Wang Hao personally announced that he would give him a bonus support, and the bonus is still 500,000 yuan, which can naturally attract many scholars to participate.

However, there has been no progress in the study.

Many scholars in the field of mathematics even believe that functions do not make sense.

Wang Hao suddenly released news that there was a breakthrough in research, which naturally attracted a lot of attention, and even ordinary people were very concerned.

From the perspective of ordinary people, Wang Hao is different from other mathematical physicists.

This is not about achievements, but about his field of study. Many mathematicians and physicists are also at the forefront of science, but the content of their research is completely incomprehensible to ordinary people.

Most scientists are also at the forefront of research, but their research is incomprehensible to ordinary people and is basically out of touch with technology. Especially theoretical physics, and basic mathematics.

For example, some basic mathematics research, most of them can't even understand the title, so naturally they are not interested. Wang Hao is different.

Superconductivity, anti-gravity, and science and technology are directly related, and the current research is also a theory, which does annihilate the most basic content of physics, especially the research of basic mathematics, the top research in some disciplines, and it is not even easy to understand the title.

Wang Hao's research is different, he not only studies theory, but also studies science and technology, anti-gravity technology, superconductivity theory, are direct scientific and technological research.

He led the team to build the most talked-about anti-gravity vehicle.

The function that is taken out now is indeed incomprehensible to ordinary people, but it has been discussed once before, and many scholars have popularized Wang Hao's research, which can naturally make people know its significance-

"The study of the Wang's function is related to the mass point architecture."

"If we can complete the framework of annihilating the most basic mass points of physics, we will be able to connect the other three microscopic forces and realize the unification of physics."

How remarkable is that?

In the world of theoretical physics, string theory is also considered to be a grand unification theory, but almost everyone knows that it is impossible, and the grand unification of string theory is just an imagination.

One is that many of the contents of string theory, including the eleven-dimensional space and the membrane universe, sound a bit unreliable, difficult to get close to real life, and deviate far from conventional physics.

Also, it is important to note that string theory has not been proven.

String theory holds that the basic unit of matter is the string, but there is no experiment to verify it.

A theory that has not been proven

Even if the theory can be unified, it is not certain whether it is true or not. Annihilation physics is different.

Because it is directly related to the research of antigravity and superconductivity, the theory has been promoted to "physics" and has been recognized by major international institutions.

In this context, the physics of annihilation can achieve the unification of physics, and it will be recognized by many people.

In short, many people know that the function that Wang Hao came up with is of great significance.

Now that Wang Hao has publicly announced the progress of his research, he will naturally become the focus of public opinion, and the information he released is indeed very amazing.

"If my understanding is correct, is Wang Hao saying that after substituting a few prime numbers, the transformed equation can still find prime numbers?"

"And there's more than one group!"

This alone is amazing enough, even the student body of ordinary universities can roughly understand how significant the significance of many 'prime number ungrouping' is, which probably shows that the so-called 'higher prime point function', that is, 'Wang's function', contains the law of prime numbers.

The law of prime numbers can be said to be the ultimate pursuit of basic mathematical research.

Many people know that there is no law to the existence of prime numbers, but in terms of the principle of the existence of prime numbers, there are laws in theory.

That's the paradox.

Theoretically, there is a law to the existence of prime numbers, but in practice, there is no law at all.

Because of this, there are so many mathematical conjectures related to the existence of prime numbers in number theory.

Some mathematicians believe that "if we can crack the laws of prime numbers, we will be able to understand the lowest mysteries of the universe." This is not an exaggeration.

Thinking about it from this point of view, we know how shocking it is that Wang Hao released the content that there are multiple sets of 'prime number solution points' in the higher-order prime point function.

There are two things explained at the back of the news, one and Wang Hao decided to give Zhu Kuiyang a reward of 800,000 kinds of flower coins, which can be regarded as fulfilling his promise; The other is related to the release of the results, and the research paper will be published together in the new issue of "New Advances in Mathematics".

At the same time, in the second article, "Specificity of Higher Order Particle Functions", Zhu Kuiyang will also be listed in the author column, and his contribution to the research will be highlighted.

In this way, many people also discussed Zhu Kuiyang.

If he is a well-known scholar in the field of mathematics who has helped Wang Hao in his research, it doesn't sound like a big deal.

It's different if it's a Ph.D. student, and many people exclaimed on the Internet, "Zhu Kuiyang, definitely a genius!"

"The Ph.D. students at Eastport Polytechnic University are amazing, but the Department of Mathematics at Eastport Polytechnic University.... cough cough ..... "It's really amazing, I can't imagine that I can help Wang Hao in my twenties!"

Everyone knows that Zhu Kuiyang's future is promising.

However, in the field of mathematics, many scholars are also surprised by Zhu Kuiyang, but the really top scholars pay more attention to the study of higher-order particle functions themselves.

No doubt.....

When a function determines that there are many 'all-prime points', it must be very unusual, but the message released by Wang Hao is also very vague, and it is uncertain whether there are 'countless all-prime points' or only a few all-prime points.

The meaning of the former and the latter are not at all on the same level. They didn't have to wait long.

Wang Hao is not an ordinary scholar, and his contributions will be released as soon as possible.

Bruce Pulitzer, the editor-in-chief of New Advances in Mathematics, is also an old friend, and Pulitzer knew what to do as soon as he received his submission.

Leave it as it is and quickly put it on the official website!

In order to achieve the maximum effect, even the papers placed on the official website are free of charge, and can be downloaded directly as long as you register as a member.

Therefore, it only took less than a day to find the introduction and download links of the two papers on the homepage of the official website of "New Advances in Mathematics".

The name of the first paper is "Constructing a Higher Order Particle Function Based on the Riemann Function", and the first author of the paper is Wang Hao.

Ding Zhiqiang and Qiu Hui'an were quilted

Mark up as other contributing collaborators.

The content of this paper is complex and describes the derivation process of the higher-order particle function.

The title of the second article is "A Study on the Specificity of Higher Prime Point Functions", that is, it is found that '5,17' is the prime pair node of the function.

"We did 23 verifications, and the numbers were 19, 29, 31....." All the validations are able to correspond to another prime number."

This is a description of the 'higher order particle function'.

At the end of the paper, the paper concludes, "23 verifications do not mean 100% accuracy, but we are not trying to prove mathematical theorems, but to illustrate the specificity of higher-order particle functions."

Many mathematicians saw the content of the second paper and immediately began to verify it. Everyone picks up the wood and the flame is high!

In just a dozen hours, mathematicians from all over the world published the numbers they had verified and said that they had obtained another prime number.

Although none of the verified figures exceeded 1,000, to a certain extent, it was already able to illustrate the law. 5, 17, is indeed a prime pair node of a function.

When a function contains an infinite number of all-prime points and is very densely distributed, it can never be described as a coincidence.

Of course, mathematics is a rigorous subject.

Many organizations are organizing special teams to conduct further verification, and the number they have verified is more than 1,000.

Such verification is more convincing.

If it is only verified by solving, it will become very difficult to substitute larger prime numbers, after all, the speed of the human brain is limited.

Some institutions want to substitute '5 and 17' to make a flat image of the corresponding function, but soon find that they can only make an approximate image', because after substituting a single number, in most cases, the computer cannot directly solve it at all.

At this time, the top mathematics community is concerned about another problem-

"Is there any other prime pair of nodes in the higher-order prime point function?"

"How many prime pairs do there exist in a function, is it a fixed number, or an infinite number?" These two questions are too attractive.

5 and 17' are prime pairs of nodes of the higher-order prime point function, so are there other prime pairs? A lot of teams are starting to work on the problem.

In fact, just like Mersenne primes, mathematicians can find the law of Mersenne primes and are interested in discovering Mersenne primes.

A leading mathematician commented, "The study of prime pairs of nodes of higher-order particle functions is likely to become a major direction of prime number research in the future."

"This alone is enough to show that the higher-order particle function, that is, the Wang's function, has extraordinary mathematical research value!"

Donggang University of Technology.

Since Wang Hao released the news, Zhu Kuiyang's life has changed completely.

Zhu Kuiyang was in a very embarrassing situation before, he hoped to continue to engage in mathematics research, but he could not stay in school to engage in teaching and scientific research.

If he can't stay in school, he can only go to a much worse school, or go out to find a job and change industries entirely. It's different now.

Several directors of Donggang University of Technology, including department leaders, came to talk to Zhu Kuiyang in a good voice, persuaded him to stay and work in the school, and promised to be promoted to associate professor after one year of work.

One year of work is due to the requirements of associate professors, who need to work as a faculty member for one year.

Now the school is afraid that Zhu Kuiyang will leave directly, and when the time comes, it will not only be a matter of losing talents, but also the reputation of the school may be damaged.

Zhu Kuiyang not only helped Wang Hao's research and signed the most high-profile mathematical papers, but he also became a 'recognized genius'.

If Zhu Kuiyang graduates and leaves school, it is possible to cause some public opinion controversy!

Zhu Kuiyang felt like a dream, he was sure to stay in school, got a bonus of 800,000 R from Academician Wang Hao, and became the envy of his classmates.

Even..

..

Even before he officially graduated, the school 'urged' him in advance to think about the topics he would study after his employment and decided to provide financial support.

I don't dare to think of this kind of treatment!

Zhu Kuiyang didn't worry about the subject at all, he had already thought about studying Wang's function.

This direction is originally his favorite, and Wang's function is also a new direction in mathematics, and it is likely to become a popular direction in the future.

Now engaged in related research, it can be regarded as the first batch of actions.

There are many scholars who have similar ideas to Zhu Kuiyang, and every scholar knows that Wang's function has great potential and contains rich treasures.

Now is the beginning of digging, and it is easier to dig up better content in the early stage. Gotta hurry!

Many teams think the same way, not only in mathematics, but also in computing, because Wang's function is very complex, and it is very, very difficult to rely on mathematical means to study things.

Computers, different.

Wang Hao's second paper directly helped some teams point out the direction.

A team from Stanford University decided on the direction almost the same day, and they wanted to verify the prime numbers within 100,000 to see if there were other prime pairs of the function in the numbers within 1 million.

The method of this study is also very simple, which is to use a computer to perform the coverage check.

No matter how complex the function is, it is only a quaternion function, and because of its particularity, it is possible to substitute a minimum odd prime number 3', and then fix two prime numbers as a 'prime pair node alternative', and transform the function into a complex equation.

The next step is to perform the coverage check.

The computer does not need to analyze the transformed equation, but directly overwrites the substitution, starting from the number "3", verifying 3, 5, 7..., or even more than a million prime numbers, to see if there are numbers that make the calculation results on both sides of the equation the same.

The results are the same, documented.

The results are different, and the next set of 'prime pair node alternatives' can be verified.

This calculation method is very fast, and the programming is relatively simple, the only thing that needs to be verified is that the number of prime pair node options is massive.

So they applied to use the supercomputer of the stock song.