From university lecturer to chief academician.
Chapter 303 Public Theory, Nature Express Report, The End of Parsons
Philip Rohrer only talked about their findings in the experimental research, and did not explain the details in detail, but it was enough to inspire Wang Hao.
The key here is that the high magnetic field affects the antigravity field.
This one message is enough.
This is the case with many applied science and technology studies. 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 the magnetic field, but he didn't know whether to demonstrate it from theory or to do some kind of experiment.
The experimental findings illustrated by Philippe Röhrer have come at just the right time.
Add an ultra-high magnetic field to the anti-gravity equipment and the coverage area. Because of the particularity of the superconducting state, the magnetic field cannot affect the internal operation of the superconducting material.
The formation of the anti-gravity field is a manifestation of the microscopic morphology and the extinguishing force inside the superconducting material, and has no relationship with the magnetic field.
However, the high magnetic field can affect the anti-gravity field, and even make the field force directional shift, so what is affected is not the anti-gravity field, but probably the thin edge layer of the anti-gravity field.
In other words, the experimental findings of Philip Röhrer's team have a strong correlation with the edge effects of superimposed force fields.
Then the next step is to study the influence of high magnetic field on the edge of the superimposed force field.Wang Hao found the research direction, and a smile appeared on his face.
On stage.
Seeing the reactions of the audience, Philip Laurel couldn't help showing a smug smile. He explained how the high magnetic field affects the anti-gravity field, but he didn't explain the details of the experiment.
That is not to deflect the anti-gravity field by creating a high magnetic field, but requires some specific conditions and environment.
It is not so easy for other teams to reproduce the experiment.
If they want to do research together, they must cooperate with their own team, so that they can take the lead in research.
That's what Philippe Rohrer is about.
This is also very beneficial, because they have not made progress in this direction for a long time, even if their own team has been doing research, there will be no progress in a short time.
That being the case, it is naturally a good choice to make it public and cooperate with other teams, and then strive for the dominance of the research.
There was a lot of discussion in the audience.
The experimental findings published by Philip Röhrer are indeed quite astonishing.
Prior to this, there has been no discovery that can affect the antigravity field. The new discovery may mean a new research direction, or even a brand 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 slight smile, Wang Hao applauded directly and took the initiative to shake hands with him. Professor Laurel, that's amazing!
Your experimental findings are remarkable, and may lead to even greater breakthroughs in antigravity research, as well as new theories of physics.
A series of praises from Wang Hao made Luorel couldn't help but smile.
Laurel shook hands with Wang Hao, kept saying thank you, and also complimented that you are 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 the current position, 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 of getting Wang Hao's affirmation.
Later, when I shook hands with other people, it was a bit awkward in retrospect.
Indeed, Wang Hao affirmed him.
However, they are direct competitors, so what's the point of a compliment?
Even though he thought so, Laurel still couldn't help but raise the corner of his mouth, and he knew deep down that he and Wang Hao were really incomparable.
……
Noon,
Many people are discussing the effect of high magnetic fields on antigravity fields.
At the same time, they also looked forward to Wang Hao's report.
Among them are some well-informed people who already know what kind of experimental findings Wang Hao is going to announce.
For example, Philippe Rohrer.
He already knew about the magnetization effect of the edge of the superimposed force field on matter, but he didn't take it too seriously. He felt that Wang Hao made a bad move.
This experiment found that it is not worth the candle to make it public.
The reason is simple, as long as the experimental findings are made public, other teams can easily reproduce them.
Since other teams can reproduce the experiment and do their own research, why should they cooperate?
Most of the team didn't know the experimental findings that Wang Hao wanted to make public, and they were all looking forward to it.
At 01:30 in the afternoon, the meeting continued.
In the anticipation of many people, Wang Hao stood up, and he also invited Lin Wenji, Professor Lin, and we went up together.
it is good!
Lin Wenji immediately stood up excitedly.
Those who didn't know the news were a little confused, so they didn't understand why Wang Hao was going to make a report, so why did he drag Lin Wenji with him.
The two teams have nothing to do with each other, right?
Wang Hao and Lin Wenji walked onto the stage together. With a slight smile on his face, he said that this experimental discovery does not belong to the Antigravity Behavior Research Center alone.
Although it was later than our time, Professor Lin's team also made the same discovery, so I decided to disclose the news of the experiment with Professor Lin.
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 the new discovery, mainly because he came to disclose the news, and Lin Wenji might not have the opportunity to speak.
Lin Wenji looked at Wang Hao gratefully, and then said excitedly, when my team was studying the superimposed force field, it was discovered that metal objects passing through the edge of the superimposed force field would undergo a short-term magnetization reaction.
I'm sure this is 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 made the first discovery.
The second team or individual who discovers will not get any honor.
Now Wang Hao took him to the stage together, which is equivalent to sharing the honor with him. This approach is really touching.
Wang Hao didn't care at all, and pulling Lin Wenji to release the news was something he had thought about in advance. …
One is to demonstrate the practice of not coveting results.
On the other hand, Lin Wenji's team is from American no matter how they say it. Sharing a little bit of unaffected honor and past is also showing the sincerity of cooperation to other teams.
After Lin Wenji finished talking about the experimental findings, Wang Hao added that in fact, not only metals exhibit magnetization reactions, but many other materials can also, but the magnetization reactions shown are weak.
Everyone else understands this sentence.
Lin Wenji's team only detected the magnetization response of metallic substances because their experimental techniques were insufficient.
Wang Hao's research team can create a higher anti-gravity field and superimpose the strength of the edge of the force field. Higher, it can make other materials also exhibit magnetization reactions.
Many teams in the audience also thought about it, and found that the material magnetization reaction caused by the edge of the superimposed position is different from the high magnetic field effected by Philip Rohrer on the antigravity field offset.
The latter is definitely not easy to reproduce.
It is much easier to reproduce the former, and it is even said that as long as a superimposed force field of sufficient strength is created, the experiment can definitely be reproduced.
Most of the anti-gravity technologies mastered by the teams present were no worse than those of Lin Wenji's team, and they could easily do it.
Many of them want to go back and give it a try.
Wang Hao
Continuing, we have been researching in this direction for a long time and have achieved certain results.
We even said that we have perfected the relevant basic theories.
This statement surprised many people in the audience.
Wang Hao didn't care about the reactions of other people, but continued, "Next, I will demonstrate the principle of the magnetization reaction of matter caused by the edge of the superimposed force field.
After hearing this, many people took a deep breath.
If only the experimental findings were made public, they could be considered to have been discovered by chance during the course of the research.
Now that Wang Hao directly stated that the basic principles should be disclosed, the situation is completely different. It must have been studied in depth for a long time.
But here comes the problem.
Now that we have figured out the basic theory, we can just release the results directly, so why talk about collaborative research?
Wang Hao began to explain that the most basic reason for the magnetization of matter is that the interior of the atom bears a higher annihilation force, leading to a series of reactions.Electrons are squeezed to jump.
He drew a graphic of an atom on the whiteboard, with a few small black dots next to it, representing electrons.
When subjected to higher annihilation forces, atoms tend to form more stable forms.
The force between the nucleus and the electron will increase, which will cause the electron to jump inward...
The jump of electrons will not cause magnetization reaction, but when the strong annihilation force disappears and returns to the strength seen by the source, the electrons will undergo a directional rotation...
This process allows 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 electrons, jumping, not translation...
Subsequent studies have shown that there is an upper limit to the magnetization response of matter.
For example, if a certain substance is subjected to an annihilation force with an intensity of 5, the magnetization reaction that occurs is the same as when it is subjected to an annihilation force with an intensity of 6. …
However, when the intensity of the annihilation force exceeds an upper limit, the magnetization reaction of the matter will undergo a further jump, perhaps multiplying several times at once.
Under the action of strong annihilation force, the intensity of magnetization reaction of any substance is not continuous.
We can understand it as jump fluctuations.
Some areas will gradually increase, some areas will be empty, and some areas will be fixed.
This is related to the atomic composition and electron distribution of the material base.
After explaining the basic theory, Wang Hao gave everyone a period of time to digest and answered a few questions.
He then entered the main content, so the research requires a lot of experiments and a lot of data. For the magnetization reaction of many substances, and the superimposed force field effect of different intensities, special experimental research is required.
When there is enough data, it can be analyzed.
This is crucial for the analysis of the role of strong annihilation force on matter.
When Wang Hao was talking seriously, many teams in the audience had already reacted.
The edge effect of the superimposed force field, to some extent, can 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 cooperative research and view the analysis data at the first time, you will definitely get a lot of results from the data.
Just like particle collision experiments, if you get the 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 many physicists to participate.
Although the data of the particle collision experiment is also open to the public, it is only open to the participants, and other people have no permission to view it.
Even if other people can view the data later, it is 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
To pay a high investment, but to conduct the same experiment and share the data results with each other, participating in it can be said to be beneficial without any harm.
The leaders and representatives of many teams can't wait to hear it.
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 was over, many team leaders immediately expressed that they would participate in the cooperative research on the edge effect of the superimposed force field.
Afterwards, they began to discuss cooperation methods, including the establishment of a platform for sharing data, including the distribution of experimental content.
Because of the high demand for experimental data, and considering the different technical levels of each research team, the assignment of experimental work is also a headache.
This aspect needs to be discussed in detail.
In any case, other teams were determined 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 let other teams participate in collaborative research, which will speed up the research and obtain a large amount of data.
This purpose has been achieved. …
In addition, it was the news of Philip Röhrer about the influence of high magnetic fields on the antigravity field, which brought inspiration.
Wang Hao also found the next research direction.
Other teams also gained a lot. They got two important experimental information, and decided to participate in one, which will definitely have fruitful cooperative research in the future.
The experimental findings of Philip Röhrer's team have also aroused the interest of other groups, but they are only interested.
Because they know that replicating experiments is not an easy task.
If you want to really participate in the research, you must cooperate with the Laurel team, but it is simply impossible for the Laurel team to share the experimental details for free.
At that time, you will definitely pay the price.
In contrast, participating in the collaborative research proposed by Wang Hao not only does not require any sacrifice, but also will definitely produce results. Anyone knows how to choose.
Philippe Laurel became less appealing.
The only person who didn't get anything out of the meeting was Philippe Rohrer, because no other team had explicitly signed up for their research.
In addition, Wang Hao and Lin Wenji already knew the magnetization effect of the edge of the superimposed force field on matter announced by Wang Hao and Lin Wenji before he came to the conference.
In the end, Philippe Rohrer had to make it clear that he would participate in collaborative research.
He has no choice.
When other teams are participating in collaborative research, only their team will definitely fall behind if they do not participate.
Philip Laurel could only sigh bitterly in the end, he was still not ready! "
If we can also develop the basic theory and find the right research direction, we can call on other teams to participate...
However, it is not something I can do to find the right direction and even understand the basic theory!
Philip Rohrer is still self-aware. He is a standard experimental physicist. Theoretical research related to antigravity requires a scholar of annihilation theory, at least an expert in quantum physics.
He can't do it.
A week later.
The main issue of the "Nature" magazine released two flash reports on anti-gravity research.
The first news is that the Antigravity Behavior Research Center of the Florist and the High Magnetic Physics National Laboratory jointly released new progress in antigravity research.
In the research on the anti-gravity superimposed force field, both experimental teams found that the edge of the superimposed force field will cause the material to produce a magnetization reaction...
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 news is that the first international conference on anti-gravity was held in Huajiajin. Representatives of [-] international anti-gravity research teams participated in the conference and decided to work together to study the effect of strong annihilation force on matter...
Below the breaking news, there are also some interviews with the head of the anti-gravity team.
Wang Hao: Strong annihilation force represents a new direction of physics.The study of a strong annihilation force field 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 the field of new physics, we will conduct cooperative research together, which will greatly accelerate human understanding of new physics.
Spoelden: The strong annihilation force represents a new direction in physics, which we are very much looking forward to...
Ben Zach: I never thought that anti-gravity technology can also be researched cooperatively, but for a new physical system...
Florida State University, Teaching Building No. [-], classrooms on the second floor.
Parsons is conducting an open class on annihilation theory. He still has the original characteristics. After the basic explanation is completed, he will promote his own theory. Dark matter is the basis for the existence of matter.
Dark matter is directly related to the Higgs field, and our follow-up research needs to explore the relationship between the Higgs field and dark matter.
In this way, the theory of annihilation can be associated with quantum physics, providing stronger support for the standard model of particles...
In the middle of the explanation, some students raised their hands and asked, Professor Parsons, what do you think of Wang Hao's strong annihilation force theory?
Parsons immediately shook his head,
The question doesn't make sense at all.I admit that Wang Hao's theory that the strong annihilation force affects the particle behavior can indeed complement the role of dark matter in astrophysics, but the strong annihilation force is only a hypothesis after all.
I'm pretty sure that strong annihilation force doesn't exist at all!
His voice was sonorous and powerful, showing extremely strong confidence in his heart, but he found that many students were talking a lot and looked at him with strange eyes.
Parsons got it.
That kind of look is no longer just questioning, it can even be said to be 'sarcasm', which seems to be a bit of a joke.
Parsons was a little confused until a student showed him a report.
That's the content of the new issue of "Nature" magazine. It said that [-] international anti-gravity experiment teams participated in the cooperative research on the edge effect of the superimposed force field.
The important thing is...
Many top physicists stand up and affirm that the edge effect of the superimposed force field is directly related to the strong annihilation force.
Strong annihilation force does not exist?
Many top experimental teams in the world have already begun to study the strong annihilation force through experiments, and they even say that the strong annihilation force does not exist?
There is no need to doubt who the students will believe.
Parsons panicked.
Facing all the mocking eyes, he stood at a loss on the podium, and simply left with his book in his arms.
There was a heated discussion in the classroom, his research was indeed wrong!
I have always believed in Wang Hao, but I don't believe in him. At his level, he still fights with Wang Hao?
I have heard it a long time ago that the reason why many people support him is just because he is from American, not because his research is so powerful.
Professor Lin Wenji said last time that he is a liar and his research is all patchwork.
I guess, many top scholars can also see it, they just don't want to pay attention to it...
bq
The key here is that the high magnetic field affects the antigravity field.
This one message is enough.
This is the case with many applied science and technology studies. 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 the magnetic field, but he didn't know whether to demonstrate it from theory or to do some kind of experiment.
The experimental findings illustrated by Philippe Röhrer have come at just the right time.
Add an ultra-high magnetic field to the anti-gravity equipment and the coverage area. Because of the particularity of the superconducting state, the magnetic field cannot affect the internal operation of the superconducting material.
The formation of the anti-gravity field is a manifestation of the microscopic morphology and the extinguishing force inside the superconducting material, and has no relationship with the magnetic field.
However, the high magnetic field can affect the anti-gravity field, and even make the field force directional shift, so what is affected is not the anti-gravity field, but probably the thin edge layer of the anti-gravity field.
In other words, the experimental findings of Philip Röhrer's team have a strong correlation with the edge effects of superimposed force fields.
Then the next step is to study the influence of high magnetic field on the edge of the superimposed force field.Wang Hao found the research direction, and a smile appeared on his face.
On stage.
Seeing the reactions of the audience, Philip Laurel couldn't help showing a smug smile. He explained how the high magnetic field affects the anti-gravity field, but he didn't explain the details of the experiment.
That is not to deflect the anti-gravity field by creating a high magnetic field, but requires some specific conditions and environment.
It is not so easy for other teams to reproduce the experiment.
If they want to do research together, they must cooperate with their own team, so that they can take the lead in research.
That's what Philippe Rohrer is about.
This is also very beneficial, because they have not made progress in this direction for a long time, even if their own team has been doing research, there will be no progress in a short time.
That being the case, it is naturally a good choice to make it public and cooperate with other teams, and then strive for the dominance of the research.
There was a lot of discussion in the audience.
The experimental findings published by Philip Röhrer are indeed quite astonishing.
Prior to this, there has been no discovery that can affect the antigravity field. The new discovery may mean a new research direction, or even a brand 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 slight smile, Wang Hao applauded directly and took the initiative to shake hands with him. Professor Laurel, that's amazing!
Your experimental findings are remarkable, and may lead to even greater breakthroughs in antigravity research, as well as new theories of physics.
A series of praises from Wang Hao made Luorel couldn't help but smile.
Laurel shook hands with Wang Hao, kept saying thank you, and also complimented that you are 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 the current position, 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 of getting Wang Hao's affirmation.
Later, when I shook hands with other people, it was a bit awkward in retrospect.
Indeed, Wang Hao affirmed him.
However, they are direct competitors, so what's the point of a compliment?
Even though he thought so, Laurel still couldn't help but raise the corner of his mouth, and he knew deep down that he and Wang Hao were really incomparable.
……
Noon,
Many people are discussing the effect of high magnetic fields on antigravity fields.
At the same time, they also looked forward to Wang Hao's report.
Among them are some well-informed people who already know what kind of experimental findings Wang Hao is going to announce.
For example, Philippe Rohrer.
He already knew about the magnetization effect of the edge of the superimposed force field on matter, but he didn't take it too seriously. He felt that Wang Hao made a bad move.
This experiment found that it is not worth the candle to make it public.
The reason is simple, as long as the experimental findings are made public, other teams can easily reproduce them.
Since other teams can reproduce the experiment and do their own research, why should they cooperate?
Most of the team didn't know the experimental findings that Wang Hao wanted to make public, and they were all looking forward to it.
At 01:30 in the afternoon, the meeting continued.
In the anticipation of many people, Wang Hao stood up, and he also invited Lin Wenji, Professor Lin, and we went up together.
it is good!
Lin Wenji immediately stood up excitedly.
Those who didn't know the news were a little confused, so they didn't understand why Wang Hao was going to make a report, so why did he drag Lin Wenji with him.
The two teams have nothing to do with each other, right?
Wang Hao and Lin Wenji walked onto the stage together. With a slight smile on his face, he said that this experimental discovery does not belong to the Antigravity Behavior Research Center alone.
Although it was later than our time, Professor Lin's team also made the same discovery, so I decided to disclose the news of the experiment with Professor Lin.
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 the new discovery, mainly because he came to disclose the news, and Lin Wenji might not have the opportunity to speak.
Lin Wenji looked at Wang Hao gratefully, and then said excitedly, when my team was studying the superimposed force field, it was discovered that metal objects passing through the edge of the superimposed force field would undergo a short-term magnetization reaction.
I'm sure this is 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 made the first discovery.
The second team or individual who discovers will not get any honor.
Now Wang Hao took him to the stage together, which is equivalent to sharing the honor with him. This approach is really touching.
Wang Hao didn't care at all, and pulling Lin Wenji to release the news was something he had thought about in advance. …
One is to demonstrate the practice of not coveting results.
On the other hand, Lin Wenji's team is from American no matter how they say it. Sharing a little bit of unaffected honor and past is also showing the sincerity of cooperation to other teams.
After Lin Wenji finished talking about the experimental findings, Wang Hao added that in fact, not only metals exhibit magnetization reactions, but many other materials can also, but the magnetization reactions shown are weak.
Everyone else understands this sentence.
Lin Wenji's team only detected the magnetization response of metallic substances because their experimental techniques were insufficient.
Wang Hao's research team can create a higher anti-gravity field and superimpose the strength of the edge of the force field. Higher, it can make other materials also exhibit magnetization reactions.
Many teams in the audience also thought about it, and found that the material magnetization reaction caused by the edge of the superimposed position is different from the high magnetic field effected by Philip Rohrer on the antigravity field offset.
The latter is definitely not easy to reproduce.
It is much easier to reproduce the former, and it is even said that as long as a superimposed force field of sufficient strength is created, the experiment can definitely be reproduced.
Most of the anti-gravity technologies mastered by the teams present were no worse than those of Lin Wenji's team, and they could easily do it.
Many of them want to go back and give it a try.
Wang Hao
Continuing, we have been researching in this direction for a long time and have achieved certain results.
We even said that we have perfected the relevant basic theories.
This statement surprised many people in the audience.
Wang Hao didn't care about the reactions of other people, but continued, "Next, I will demonstrate the principle of the magnetization reaction of matter caused by the edge of the superimposed force field.
After hearing this, many people took a deep breath.
If only the experimental findings were made public, they could be considered to have been discovered by chance during the course of the research.
Now that Wang Hao directly stated that the basic principles should be disclosed, the situation is completely different. It must have been studied in depth for a long time.
But here comes the problem.
Now that we have figured out the basic theory, we can just release the results directly, so why talk about collaborative research?
Wang Hao began to explain that the most basic reason for the magnetization of matter is that the interior of the atom bears a higher annihilation force, leading to a series of reactions.Electrons are squeezed to jump.
He drew a graphic of an atom on the whiteboard, with a few small black dots next to it, representing electrons.
When subjected to higher annihilation forces, atoms tend to form more stable forms.
The force between the nucleus and the electron will increase, which will cause the electron to jump inward...
The jump of electrons will not cause magnetization reaction, but when the strong annihilation force disappears and returns to the strength seen by the source, the electrons will undergo a directional rotation...
This process allows 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 electrons, jumping, not translation...
Subsequent studies have shown that there is an upper limit to the magnetization response of matter.
For example, if a certain substance is subjected to an annihilation force with an intensity of 5, the magnetization reaction that occurs is the same as when it is subjected to an annihilation force with an intensity of 6. …
However, when the intensity of the annihilation force exceeds an upper limit, the magnetization reaction of the matter will undergo a further jump, perhaps multiplying several times at once.
Under the action of strong annihilation force, the intensity of magnetization reaction of any substance is not continuous.
We can understand it as jump fluctuations.
Some areas will gradually increase, some areas will be empty, and some areas will be fixed.
This is related to the atomic composition and electron distribution of the material base.
After explaining the basic theory, Wang Hao gave everyone a period of time to digest and answered a few questions.
He then entered the main content, so the research requires a lot of experiments and a lot of data. For the magnetization reaction of many substances, and the superimposed force field effect of different intensities, special experimental research is required.
When there is enough data, it can be analyzed.
This is crucial for the analysis of the role of strong annihilation force on matter.
When Wang Hao was talking seriously, many teams in the audience had already reacted.
The edge effect of the superimposed force field, to some extent, can 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 cooperative research and view the analysis data at the first time, you will definitely get a lot of results from the data.
Just like particle collision experiments, if you get the 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 many physicists to participate.
Although the data of the particle collision experiment is also open to the public, it is only open to the participants, and other people have no permission to view it.
Even if other people can view the data later, it is 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
To pay a high investment, but to conduct the same experiment and share the data results with each other, participating in it can be said to be beneficial without any harm.
The leaders and representatives of many teams can't wait to hear it.
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 was over, many team leaders immediately expressed that they would participate in the cooperative research on the edge effect of the superimposed force field.
Afterwards, they began to discuss cooperation methods, including the establishment of a platform for sharing data, including the distribution of experimental content.
Because of the high demand for experimental data, and considering the different technical levels of each research team, the assignment of experimental work is also a headache.
This aspect needs to be discussed in detail.
In any case, other teams were determined 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 let other teams participate in collaborative research, which will speed up the research and obtain a large amount of data.
This purpose has been achieved. …
In addition, it was the news of Philip Röhrer about the influence of high magnetic fields on the antigravity field, which brought inspiration.
Wang Hao also found the next research direction.
Other teams also gained a lot. They got two important experimental information, and decided to participate in one, which will definitely have fruitful cooperative research in the future.
The experimental findings of Philip Röhrer's team have also aroused the interest of other groups, but they are only interested.
Because they know that replicating experiments is not an easy task.
If you want to really participate in the research, you must cooperate with the Laurel team, but it is simply impossible for the Laurel team to share the experimental details for free.
At that time, you will definitely pay the price.
In contrast, participating in the collaborative research proposed by Wang Hao not only does not require any sacrifice, but also will definitely produce results. Anyone knows how to choose.
Philippe Laurel became less appealing.
The only person who didn't get anything out of the meeting was Philippe Rohrer, because no other team had explicitly signed up for their research.
In addition, Wang Hao and Lin Wenji already knew the magnetization effect of the edge of the superimposed force field on matter announced by Wang Hao and Lin Wenji before he came to the conference.
In the end, Philippe Rohrer had to make it clear that he would participate in collaborative research.
He has no choice.
When other teams are participating in collaborative research, only their team will definitely fall behind if they do not participate.
Philip Laurel could only sigh bitterly in the end, he was still not ready! "
If we can also develop the basic theory and find the right research direction, we can call on other teams to participate...
However, it is not something I can do to find the right direction and even understand the basic theory!
Philip Rohrer is still self-aware. He is a standard experimental physicist. Theoretical research related to antigravity requires a scholar of annihilation theory, at least an expert in quantum physics.
He can't do it.
A week later.
The main issue of the "Nature" magazine released two flash reports on anti-gravity research.
The first news is that the Antigravity Behavior Research Center of the Florist and the High Magnetic Physics National Laboratory jointly released new progress in antigravity research.
In the research on the anti-gravity superimposed force field, both experimental teams found that the edge of the superimposed force field will cause the material to produce a magnetization reaction...
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 news is that the first international conference on anti-gravity was held in Huajiajin. Representatives of [-] international anti-gravity research teams participated in the conference and decided to work together to study the effect of strong annihilation force on matter...
Below the breaking news, there are also some interviews with the head of the anti-gravity team.
Wang Hao: Strong annihilation force represents a new direction of physics.The study of a strong annihilation force field 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 the field of new physics, we will conduct cooperative research together, which will greatly accelerate human understanding of new physics.
Spoelden: The strong annihilation force represents a new direction in physics, which we are very much looking forward to...
Ben Zach: I never thought that anti-gravity technology can also be researched cooperatively, but for a new physical system...
Florida State University, Teaching Building No. [-], classrooms on the second floor.
Parsons is conducting an open class on annihilation theory. He still has the original characteristics. After the basic explanation is completed, he will promote his own theory. Dark matter is the basis for the existence of matter.
Dark matter is directly related to the Higgs field, and our follow-up research needs to explore the relationship between the Higgs field and dark matter.
In this way, the theory of annihilation can be associated with quantum physics, providing stronger support for the standard model of particles...
In the middle of the explanation, some students raised their hands and asked, Professor Parsons, what do you think of Wang Hao's strong annihilation force theory?
Parsons immediately shook his head,
The question doesn't make sense at all.I admit that Wang Hao's theory that the strong annihilation force affects the particle behavior can indeed complement the role of dark matter in astrophysics, but the strong annihilation force is only a hypothesis after all.
I'm pretty sure that strong annihilation force doesn't exist at all!
His voice was sonorous and powerful, showing extremely strong confidence in his heart, but he found that many students were talking a lot and looked at him with strange eyes.
Parsons got it.
That kind of look is no longer just questioning, it can even be said to be 'sarcasm', which seems to be a bit of a joke.
Parsons was a little confused until a student showed him a report.
That's the content of the new issue of "Nature" magazine. It said that [-] international anti-gravity experiment teams participated in the cooperative research on the edge effect of the superimposed force field.
The important thing is...
Many top physicists stand up and affirm that the edge effect of the superimposed force field is directly related to the strong annihilation force.
Strong annihilation force does not exist?
Many top experimental teams in the world have already begun to study the strong annihilation force through experiments, and they even say that the strong annihilation force does not exist?
There is no need to doubt who the students will believe.
Parsons panicked.
Facing all the mocking eyes, he stood at a loss on the podium, and simply left with his book in his arms.
There was a heated discussion in the classroom, his research was indeed wrong!
I have always believed in Wang Hao, but I don't believe in him. At his level, he still fights with Wang Hao?
I have heard it a long time ago that the reason why many people support him is just because he is from American, not because his research is so powerful.
Professor Lin Wenji said last time that he is a liar and his research is all patchwork.
I guess, many top scholars can also see it, they just don't want to pay attention to it...
bq
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