Chapter 303 Public Theory, 'Nature' Express Report, Parson
The end of Sri Lanka
Philip Rohrer only talked about what they found in experimental research, without explaining the details in detail, but it was enough to inspire Wang Hao.
The key is that "high magnetic fields will affect the antigravity field."
This piece of information is enough.
A lot of applied science and technology research is like this. Just a few words, or talking about some key content, is enough to reveal a lot of valuable information.
Wang Hao has always known that the study of strong annihilation force may be related to magnetic field issues, but he didn't know whether to demonstrate it theoretically or to conduct some kind of experiment.
The experimental findings explained by Philippe Rohrer come at the right time.
Apply an ultra-high magnetic field to the anti-gravity equipment and the coverage area. Due to the special nature of the superconducting state, the magnetic field cannot affect the internal operation of the superconducting material.
The formation of the antigravity field is a manifestation of the interaction between the internal microscopic morphology and annihilation force of the superconducting material, and has nothing to do with the magnetic field.
However, a high magnetic field can affect the anti-gravity field, and even cause the field force to directionally shift. Then it is not the anti-gravity field that is affected, but probably the thin edge layer of the anti-gravity field.
In other words, the experimental findings of Philippe Rohrer's team are closely related to the edge effect of the superimposed force field.
"Then the next step is to study the impact of high magnetic fields on the edge of the superimposed force field." Wang Hao found the research direction and couldn't help but smile.
On stage at the venue.
Philip Rohrer looked at the reaction of everyone in the audience and couldn't help but smile proudly. He explained the reason why the high magnetic field affects the antigravity field, but did not explain the details of the experiment.
That does not mean that creating a high magnetic field can deflect the antigravity field, but requires some specific conditions and environments.
It is not so easy for other teams to replicate the experiment.
If they want to do research together, they must cooperate with their own team, so that they can take the lead in the research.
This is what Philippe Rohrer is for.
This is also very beneficial, because they have made no progress in this direction. Even if their own team keeps doing research, there will be no progress in a short time.
In this case, it is naturally a good choice to make it public and cooperate with other teams, and then win the leadership of the research.
Everyone in the audience was talking a lot.
The experimental findings published by Philip Rohrer are indeed very surprising.
Before this, there has not been any discovery that can affect the antigravity field. The new discovery is likely to mean a new research direction, or even a completely new system, which may help to achieve a leap forward in the field of antigravity research and basic physical theory.
breakthrough.
When Philip Laurel explained the experiment again and walked off the stage with a smile, Wang Haodu clapped his hands and took the initiative to go over and shake hands with him, "Professor Laurel, you are amazing!"
"Your experimental findings are very remarkable. They may lead to greater breakthroughs in antigravity research and explore new physical theories."
Wang Hao's series of praises made Laurel smile.
Laurel shook hands with Wang Hao and kept saying thank you and complimenting, "You have gone deeper than us in the direction of anti-gravity research, and your transverse field force technology has already been applied."
He was referring to the anti-gravity maglev train project.
This project is also currently the only technological application of anti-gravity technology, and it can even be said to be a ‘mature application’.
Laurel did compliment Wang Hao, but he couldn't help but feel a little proud after getting Wang Hao's approval.
Later, when I shook hands with other people, I felt a little awkward in retrospect.
Indeed, Wang Hao confirmed him.
However, they are direct competitors, so what's the big deal about compliments from their opponents?
Although he thought so, Laurel couldn't help but curl up his lips. Deep down in his heart, he knew that he and Wang Hao were indeed incomparable.
…
At noon, many people were discussing the impact of high magnetic fields on antigravity fields.
At the same time, they are also looking forward to Wang Hao's report.
Some of them are well-informed people and already know what kind of experimental findings Wang Hao wants to announce.
For example, Philip Rohrer.
He already knew about the magnetization effect of superimposed force field edges on matter, but he didn't take it too seriously. He felt that Wang Hao had made a bad move.
This experimental discovery is not worth the gain if it is made public.
The reason is simple. As long as the experimental findings are made public, other teams can easily replicate them.
Since other teams can replicate the experiment and do their own research, why do we need to cooperate?
Most of the team didn't know about Wang Hao's experimental findings, and they were looking forward to it.
At 1:30 p.m., the meeting continued.
In the expectation of many people, Wang Hao stood up and invited Lin Wenji, "Professor Lin, let's go up together."
"good!"
Lin Wenji immediately stood up excitedly.
People who didn't know the news were a little confused. They didn't understand why Wang Hao wanted to bring Lin Wenji along with him when he was going to make a report.
The two teams have nothing to do with each other, right?
Wang Hao and Lin Wenji walked onto the stage together. With a faint smile on his face, he said, "This experimental discovery does not belong exclusively to the Antigravity Behavior Research Center."
"Although it was later than ours, Professor Lin's team also made the same discovery, so I decided to disclose the experimental news together with Professor Lin."
"Now let's invite Professor Lin Wenji to announce the news!"
Wang Hao gave Lin Wenji a lot of face and asked Lin Wenji to disclose new discoveries, mainly because if he disclosed the information, Lin Wenji might not have a chance to speak.
Lin Wenji looked at Wang Hao with gratitude, and then said with excitement, "When my team was studying the superimposed force field, they discovered that metal materials will undergo a brief magnetization reaction when they pass through the edge of the superimposed force field."
"I was sure this was an amazing discovery, but I didn't expect that Professor Wang Hao's team had already made the same discovery."
He was truly grateful.
In general experimental research, the first discovery is called a new discovery, and the honor only belongs to the team that makes the first discovery.
The second team or individual to discover will not receive any credit.
Now that Wang Hao is dragging him on stage, he is sharing the honor with him. This approach is really touching.
Wang Hao, on the other hand, didn't care at all. He took Lin Wenji together to reveal the news, which was something he had planned in advance.
One is to demonstrate the approach of ‘not coveting results’.
On the other hand, Lin Wenji's team is from Amrikan no matter what. Sharing the honorary past that does not affect it also shows the sincerity of cooperation to other teams.
After Lin Wenji finished talking about the experimental findings, Wang Hao added, "Actually, it is not only metal materials that show magnetization reactions, many other materials can also do it, but the magnetization reactions they show are weak."
Everyone else understands this sentence.
Lin Wenji's team only detected the magnetization reaction of metallic substances because their experimental technology was insufficient.
Wang Hao's research team can create a higher anti-gravity field, and the edge of the superimposed force field will be stronger, which can cause other materials to also show magnetization reactions.
Many teams in the audience also pondered and found that the magnetization reaction of materials caused by the edge of the superposition position was different from the anti-gravity field deflection affected by high magnetic fields disclosed by Philip Rohrer.
The latter is definitely not easy to reproduce.
It is much easier to reproduce the former. It is even said that as long as a superposition force field of sufficient strength is created, the experiment can definitely be reproduced.
Most of the anti-gravity technologies mastered by the teams present are no worse than those of Lin Wenji's team, and they can all do it easily.
Many of them want to go back and give it a try.
Wang Hao continued, "We have been studying this direction for a long time and have achieved certain results."
"It's even said that we have improved the relevant basic theories."
This statement surprised many people in the audience.
Wang Hao did not care about the reactions of others, but continued, "Next, I will demonstrate the principle of the magnetization reaction of materials caused by the edge of the superimposed force field."
Many people took a deep breath after hearing this.
If they only disclose experimental findings, they can consider them to be discovered by chance during the research process.
Now that Wang Hao directly stated that he wanted to disclose the basic principles, the situation is completely different. He must have studied it in depth for a long time.
However, here comes the problem.
Now that we have figured out the basic theory, we can just publish the results directly. Why should we talk about collaborative research?
Wang Hao began to explain, "The most basic reason why matter is magnetized is that the atoms are subjected to a higher annihilation force, which leads to a series of reactions. The electrons are squeezed and jumped."
He drew a picture of an atom on the whiteboard and added a few small black dots next to it, which represented electrons.
"When subjected to higher annihilation forces, atoms tend to form more stable forms."
"The force between the nucleus and the electrons will increase, which will cause the electrons to jump inwards..."
"The electron jump will not cause a magnetization reaction, but when the strong annihilation force disappears and returns to the intensity seen from the source, the electron will rotate in a directional direction..."
"This process causes the material to undergo a magnetization reaction."
"There is also an upper limit to the magnetization reaction, which is mainly affected by the orbit of the electrons, jumping, not translation..."
The subsequent content of the study shows that there is an upper limit to the magnetization reaction of matter.
For example, if a substance is subjected to an annihilation force with a strength of 5, the magnetization reaction that occurs is the same as the magnetization reaction with a strength of 6.
However, when the intensity of the annihilation force exceeds an upper limit, the magnetization reaction of the material will jump to the next step, perhaps multiplying several times in one fell swoop.
"The intensity of the magnetization reaction that occurs in any substance under the action of a strong annihilation force is not continuous."
"We can understand it as a jump fluctuation."
"Some areas will gradually increase, some areas will sell out, and some areas will remain static."
"This is related to the atomic composition and electron distribution of the basis of matter."
After explaining the basic theory, Wang Hao gave everyone some time to digest and answered a few questions.
He then entered the main content, "Therefore, research requires a large amount of experiments and a large amount of data. Special experimental research must be done on the magnetization reactions of many materials and the superimposed force field effects of different strengths."
"When you have enough data, you can analyze it."
"This is crucial for the analysis of the effect of strong annihilation force on matter."
When Wang Haozheng was speaking seriously, many teams in the audience had already reacted.
The edge effect of the superposed force field can, to a certain extent, be understood as the 'effect of the strong annihilation force on matter'.
This kind of research definitely requires a lot of data.
If you can participate in collaborative research and view the analyzed data immediately, you will definitely get a lot of results from the data.
Just like a particle collision experiment, if you get first-hand data and analyze the data first-hand, you can easily get a lot of results and publish many influential papers.
This is also the reason why particle collision experiments attract the participation of many physicists.
Although the data of the particle collision experiment is also open to the public, the disclosure is only open to the participants, and others do not have permission to view it.
Even if others can view the data later, it will be difficult to analyze new content because the relevant data has been analyzed several times.
The current research is not a large-scale particle collision experiment. They do not need to go to the experimental site to participate in the research, nor do they need to pay high investment. They just conduct the same experiment and share the data results with each other. Participating in it can be said to be a huge benefit.
No harm done.
Many team leaders and representatives sounded impatient.
Wang Hao not only disclosed a result, but also helped them find a research direction that would definitely yield results.
…
Wang Hao’s report can be said to be a great success.
After the report ended, many team leaders immediately expressed their willingness to participate in collaborative research on the edge effects of superimposed force fields.
Afterwards, they began to discuss ways to cooperate, including establishing a platform for sharing data, including the distribution of experimental content.
Because the demand for experimental data is very high, and considering the different technical levels of each research team, the allocation of experimental work is also a headache.
This aspect needs to be discussed in detail.
In any case, other teams decided to participate in collaborative research, and the meeting can be said to be a great success.
Wang Hao has also gained a lot. His main purpose is to involve other teams in collaborative research, which will speed up the research and obtain a large amount of data.
This purpose has been achieved.
In addition, the inspiration brought by Philip Rohrer's news about the impact of high magnetic fields on anti-gravity fields was harvested.
Wang Hao also found the next research direction.
Other teams also gained a lot. They obtained two important experimental information and decided to participate in a collaborative research that will definitely be fruitful in the future.
The experimental findings of Philip Rohrer's team have also aroused the interest of other teams, but they are only interested.
Because they know that replicating experiments is not easy.
If you want to truly participate in the research, you must cooperate with the Rohrer team, but it is simply impossible for the Rohrer team to share experimental details for free.
When the time comes, you will definitely pay the price.
In comparison, participating in the cooperative research proposed by Wang Hao not only requires no effort, but will definitely yield results. Everyone knows how to choose.
Philippe Rohrer has become less attractive.
Throughout the meeting, the only person who had nothing to gain was Philip Rohrer, because no other team had explicitly expressed participation in their research.
In addition, he already knew about the magnetization effect on matter at the edge of the superposed force field announced by Wang Hao and Lin Wenji before coming to the meeting.
In the end Philippe Laurel had to make it clear that he would participate in collaborative research.
He has no choice.
When other teams participate in collaborative research, their team will definitely fall behind if they do not participate.
Philip Rohrer could only sigh bitterly in the end, "I'm still not ready!"
"If we can also study the basic theory and find the correct research direction, we can call on other teams to participate..."
"However, being able to find the right direction and even understand the basic theory is not something I can do!"
Philip Rohrer is still self-aware. He is a standard experimental physicist. Theoretical research related to antigravity requires scholars of annihilation theory and at least experts in quantum physics.
He can't do it.
…
One week later.
The main magazine "Nature" published two news reports on antigravity research.
The first news was, "The Antigravity Behavior Research Center of the Florist and the National Laboratory of High Magnetic Physics jointly released new progress in antigravity research."
"In the study of antigravity superimposed force fields, both experimental teams found that the edges of the superimposed force fields will cause magnetization reactions in materials..."
"In this regard, Professor Wang Hao analyzed the theoretical mechanism and believed that the edge of the superimposed force field is related to the strong annihilation force..."
The second message was, "The first international anti-gravity conference was held in Kaishi, Zhonghuajiajin. Representatives of eighteen international anti-gravity research teams participated in the conference and decided to work together to study the effects of strong annihilation forces on matter..."
Below the flash news, there are also some interviews with the leaders of the anti-gravity team.
Wang Hao: "Strong annihilation force represents a new physical direction. Research on strong annihilation force fields will make a qualitative leap in human technology..."
Lin Wenji: "The edge effect of the superimposed force field is directly related to the strong annihilation force. In new physics fields, our collaborative research will greatly accelerate mankind's understanding of new physics."
Sporden: "The strong annihilation force represents a new physical direction, and we are very much looking forward to it..."
Ben Zucker: "I never thought that anti-gravity technology could also be researched together, but for a completely new physical system..."
Florida State University, Classroom No. 3, Classroom on the Second Floor.
Parsons is giving an open class on annihilation theory, and he still has the same characteristics as before. After completing the basic explanation, he promoted his own theory, "Dark matter is the basis of the existence of matter."
"Dark matter is directly related to the Higgs field. Our subsequent research needs to explore the relationship between the Higgs field and dark matter."
"In this way, the annihilation theory can be connected with quantum physics, providing stronger support for the standard model of particles..."
In the middle of the explanation, a student raised his hand and asked, "Professor Parsons, what do you think of Wang Hao's theory of strong annihilation force?"
Parsons immediately shook his head,
"This question is meaningless at all. I admit that Wang Hao's theory that strong annihilation force affects particle properties can indeed complement the role of dark matter in astronomy. However, strong annihilation force is just a hypothesis after all."
"I am very sure that strong annihilation force does not exist at all!"
His words were sonorous and powerful, showing extremely strong confidence in his heart, but he found that many students were talking about it and looked at him with strange eyes.
Parsons understood.
That look was no longer just questioning, it could even be said to be 'ridiculing', it seemed like he was looking at a joke.
Parsons was confused until a student showed him a report.
That's the content of a new issue of Nature magazine. It says that eighteen international anti-gravity experimental teams are participating in collaborative research on the edge effect of superimposed force fields.
The important thing is...
Many top physicists have come forward to confirm that the edge effect of the superposition force field is directly related to the strong annihilation force.
Strong annihilation force does not exist?
Many top experimental teams in the world have begun to study strong annihilation force through experiments, but they still say that strong annihilation force does not exist?
There is no need to doubt who the students will believe.
Parsons suddenly panicked.
Facing the mocking looks, he stood on the podium at a loss and simply left with his book in his arms.
There was a lively discussion in the classroom, "His research is indeed wrong!"
"I have always believed in Wang Hao. If I don't believe in him, why would he still compete with Wang Hao at his level?"
"I've heard it a long time ago. The reason why many people support him is just because he is an Amerikan. It doesn't mean how powerful his research is."
"Professor Lin Wenji said last time that he is a liar and his research is all pieced together."
"I estimate that many top scholars can also see it. They just don't want to pay attention to it..."