:I don’t understand!
There are four basic forces in physics, namely gravity, electromagnetic force, strong nuclear force and weak nuclear force.
The electromagnetic force is the second most powerful force after the strong nuclear force.
The four major forces of physics have been explained in great detail, but basic physics is still being studied continuously, and some very important experiments will be conducted in order to achieve the unification of the four major forces.
This is the ultimate goal of physical research.
Any new and logical explanation of the four powerful forces can be said to be a very amazing result, because the research will bring understanding from different perspectives and help the scientific community expand the direction of research and development and thinking.
However, the more basic the research, the more difficult it is.
Regarding the basic explanation of electromagnetic force, there have been no impressive results in recent decades.
In addition, there are very few theoretical physicists who will study and explain the most basic forces. They prefer to improve the standard model of particles, understand the basic composition of the universe, and analyze black holes, big bangs, antimatter, dark matter, etc.
This may also have something to do with difficulty.
Each basic force has been explained in detail, and it is very, very difficult to understand it from other perspectives.
The same is true for electromagnetic force.
When they heard that Wang Hao said that he would use new geometry to explain electromagnetic force, many people at the report meeting were surprised and started discussing, "Use a completely new method to explain electromagnetic force? How is this possible?"
"Isn't this kind of research too difficult?"
"It's a bit ridiculous..."
"I can't figure out why the new geometry he mentioned can be connected with electromagnetic force?"
"Is it condensed matter physics?"
Someone soon figured out the key.
The top international scholars are all very capable. Even if they are doing mathematics-related research, they must have some exposure to basic physics.
If geometric problems can be linked to basic mechanics, the most likely field is condensed matter physics. At the same time, many people are also concerned about Wang Hao's "research on physical problems."
This is the key.
In the eyes of the international mathematics community, Wang Hao is the future of basic mathematics. They still expect him to be successful in other researches. Why did he suddenly study physics problems?
Although it still uses mathematical methods, it is still unacceptable no matter how you think about it.
"Why did Wang Hao study physics?"
"Mathematics is the most important thing about electromagnetic force and the four major forces. Only with mathematics can we have physics. Even Einstein had to use Riemannian geometry as the basis to construct his general theory of relativity!"
"Don't study physics!"
"Pure mathematics is what matters..."
Regarding the discussion at the report meeting, Wang Hao could not hear it. He just answered a question and then chose to disconnect because he was just giving a work report and talking about his research work and some progress.
He couldn't wait to count the harvest.
【Task 1】
[Research Project Name: Research on the Internal Micromorphology of Conductors (Difficulty: S).]
[Inspiration value: 77.]
"fine!"
The increase in inspiration value is not as much as expected, only about fifty points, but it is also expected.
Wang Hao is still looking forward to the report, mainly because there will be a lot of people listening to the report. He reports through video communication and there is also a live broadcast on the Internet.
Others can view the report content through live webcast.
There was some media promotion before, and the number of domestic viewers exceeded 500,000. However, the number of people later became smaller and smaller, because it was impossible for ordinary people to understand it.
But even if there are only 10,000 people, it cannot be compared in the classroom.
It's a pity that the inspiration value did not increase explosively. The improvement of nearly fifty points in twenty minutes is also very good, but it is nothing compared to the number of people.
"Similar research can hardly bring inspiration to ordinary people."
"Being able to understand is the basic threshold, but most of them can't understand, so live broadcasts for ordinary people are meaningless."
This is a pity.
Wang Hao is still thinking about another problem, "Recording videos will not be effective because the feedback of inspiration is instant."
"However, live broadcasts will also have the problem of signal delay, so will some people not provide timely feedback because of the signal delay?"
"Maybe it's because the distance is too far, but how does the inspiration reach your mind?"
"..."
When I think deeply about the problems related to the system, I find that it cannot be explained by existing science at all. This is probably because the system itself is 'unscientific', or it is far beyond the current scientific level, and it is just a judgment in the right direction.
Functions cannot be created by programs.
"Maybe it's not a one-dimensional thing?" Wang Hao finally shook his head. At least at his current level, it is impossible to understand the system.
He still focused on research.
A report meeting gave him a lot of inspiration, which also gave him confidence in his research, and he felt that he could complete it if he took further steps.
Electromagnetic force, in a broad sense, covers a wide range, such as push force, pull force, supporting force, elastic force, friction force, etc.
These forces seem to have nothing to do with electromagnetic force, but in fact, they all belong to electromagnetic force.
Electromagnetic force describes the repulsion and attraction between molecules and atoms. When objects come into contact with each other, the repulsion and attraction between atoms take the dominant position, forming a series of forces including push, pull, support, etc.
However, the research on electromagnetic force is in the "narrow sense direction", which is the direction that ordinary people conventionally understand, including electric field, magnetic field, electrostatic force, etc.
Wang Hao's research cannot cover a large range yet. For the time being, he is only studying the energized state and internal microscopic morphology of the conductor, in order to provide a new explanation for the force exerted by the magnetic field.
A current-carrying conductor will experience a force in a magnetic field; at the same time, a conductor moving in a magnetic field will generate an electric potential.
This is the knowledge of electromagnetic field force in high school physics.
Most of the current basic explanations are directly related to the movement of electrons, but in fact, it is not just electrons that participate in the reaction, because compared to the nucleus, the mass of electrons is negligible, and no matter how large the force is, it is impossible to drive the movement of the conductor.
Produce macroscopic mechanical reactions.
The process of a conductor receiving force must be the participation of atomic nuclei and its underlying basis is still the interaction between atoms.
Just like ordinary thrust, only atoms interacting with each other can produce such an obvious force.
Wang Hao's research uses the microscopic morphology within conductors to explain the interaction of current and magnetic fields.
It's all based on mathematics.
…
At the International Congress of Mathematicians, Wang Hao only gave a 20-minute work report, talking about his research content and some progress, but the impact was still great, and many people knew the news.
Among them is Wang Chenglin, chief researcher of the Basic Science Center of Capital University.
Wang Chenglin read all the reports and combined with his team's research came to a conclusion, "Wang Hao's path has gone astray."
He knows more than others.
He knew very well that Wang Hao's research was based on the AC gravity experiment, so the so-called new geometry must be directly related to the experiment.
"How can the AC gravity experiment be related to the explanation of electromagnetic force?" Wang Chenglin couldn't figure it out at all. He thought about it carefully and thought that Wang Hao still regarded the AC gravity field as a field directly related to the magnetic field and the electric field.
Only in this way can the two be linked together.
However, it is obviously not feasible to try to understand the AC gravity field using the existing basic physics.
The reason why Wang Chenglin is so confident is that their research has made progress, which can even be described as remarkable.
By analyzing the experimental data, they established a complete mathematical model, using the AC gravity field as the standard to study the relationship between temperature and materials. The next step can be to analyze which material is more likely to stimulate the superconducting state.
It is easier, that is, the excitation temperature is higher.
The goal of this research is to use mathematical analysis to try to study new high-temperature superconducting materials, and even make 'predictions' to a certain extent.
He invited four mathematical experts to specialize in related mathematical work, and the mathematical model they established was very complete.
At the same time, the work results were also recognized by the researchers of Factory 244.
In the office.
To be continued...