Golf Award
After attending the project meeting of the Science Foundation, Wang Hao returned to Xihai University. The project research has just begun, and his work life is still quite relaxed.
He spent a lot of time supervising several students' papers and submitting them.
It is almost the graduation season. Some of the students have published their papers and some are preparing to submit them.
Among them, the most labor-saving ones are Qiu Hui'an, Li Xin and Zhang Yixin. Qiu Hui'an completed the proof of Legendre's conjecture and can use it as his master's thesis.
Li Xin and Zhang Yixin have been participating in laboratory projects, and their performance has not been outstanding. However, they have been following the research and it is still very easy to complete a paper.
They are excellent students themselves. Not only did they complete their graduation thesis, they also revised and submitted it for publication in foreign magazines and entered SCI retrieval.
The papers written by Helen and Chen Mengmeng were the most laborious. They had been doing theoretical physics research with Paul Phil-Jones, and their research had indeed produced certain results.
But just because we have achieved certain results, we naturally want to do better.
Wang Hao reviewed their research and discussed it with them. Later, the research was revised several times and finally decided to submit it to the top physics journal "Physical Review Letters".
Xu Jie is a special one.
As a graduate student in the Department of Mathematics, he eventually published a research paper on mathematical computers, doing research on geometric electrical signals.
Wang Hao still cared about the content of his research, but later found that he didn't need to care at all. The one who cared most was Zhang Zhiqiang.
Xu Jie’s thesis was taught by Zhang Zhiqiang step by step.
Now Xu Jie has decided to study for a Ph.D. directly with Zhang Zhiqiang, and Zhang Zhiqiang also appreciates Xu Jie very much and plans to make him his outstanding student.
Wang Hao felt like he was being robbed by his students.
However, there is nothing we can do.
Who asked Xu Jie to do research with him, but he couldn't accomplish anything at all?
In the end I had no choice but to follow Zhang Zhiqiang.
However, to say that Xu Jie's mathematics level is poor is only compared to Helen, Qiu Hui'an and others. He is doing research in the field of mathematics and computers, and his mathematics ability is completely sufficient.
Mathematical computers are also a good direction, including Zhang Zhiqiang and Luo Dayong, their main directions are mathematical computers.
All the students under Wang Hao's guidance have completed their graduation thesis, and he feels much more relaxed. After all, he is a top scholar, and he does not want students who cannot graduate.
Scholars still have to fight for face. It's a bit embarrassing if some of the students you choose don't graduate.
After that, Wang Hao also paid attention to the Antigravity Behavior Research Center, which conducted research on the direction of the behavior of the antigravity field.
This direction is still very important.
Wang Hao is most concerned about the study of particle inertia in antigravity fields.
The reduction in the speed of light is a manifestation of particle inertia.
Although the framework theory of photons has been completed and some conclusions have been drawn, related research is still very important.
If the inertia of particles can be controlled, it will not only help improve the theory, but also have broad application prospects.
For example, will particle inertness cause nuclear reactions to slow down?
If the speed of nuclear reactions is slowed down, whether it is a fusion reaction or a nuclear fission reaction, it will be easier to control to a certain extent.
Of course, the above is not a research that can be completed by a team, and requires research and demonstration in multiple directions.
Another point that Wang Hao is concerned about is the problem of proving the existence of the space squeeze field.
In the study of photon structure shaping, the mathematical structure description of the anti-gravity field shows that the anti-gravity field has the effect of reducing the intensity of space squeeze, that is, reducing the intensity of the annihilation force.
But how to prove it?
Antigravity fields can be understood in several ways, the two most important of which are reducing the gravitational constant, which means reducing the effect of gravitational waves.
The other is to basically reduce the space squeeze and directly act on the quality of the object.
Both of these ways of understanding are possible.
According to Newton's law of universal gravitation, whether it is reducing the gravitational wave effect or reducing the mass, the gravitational effect can be reduced, and its manifestation on the earth is the gravitational effect.
At the same time, there are several other related explanations, but the above two are the most credible. Academic public opinion tends to the first one, which is to reduce the effect of gravitational waves.
Because of this, it is called ‘anti-gravity’.
Wang Hao naturally knew that it was the first type, because it reduced the space squeezing effect and directly acted on the mass of the object.
When he was thinking about the verification problem, He Yi came directly to the door and shouted, "Wang Hao, new results! The Planck Institute has proved the annihilation force!"
"Has the existence of the annihilation force been verified?" Wang Hao asked doubtfully.
He Yi nodded and sighed, "To a certain extent, it can be said that they designed a very clever and simple experiment to prove that the anti-gravity field directly acts on mass!"
"However, it is probably not easy for them. They can only create an anti-gravity field of fifteen fields."
After hearing this, Wang Hao immediately paid attention to the new results.
The German Planck Institute, which can be understood as the German Academy of Sciences, has formed an anti-gravity research team.
After Wang Hao's research group published a paper on photon architecture, many physicists around the world began to study it, and various antigravity teams also began to design experimental demonstrations.
The antigravity team of the Planck Institute is dedicated to researching the properties of antigravity fields. After understanding the results of the photon architecture, they naturally understand the mathematical expressions inside, explaining that the mechanism of the antigravity field is to create a region that reduces the space squeezing effect.
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Among them was an outstanding young researcher who designed a very clever experiment.
Taking advantage of the independent characteristics of buoyancy and mass, they conducted levitation experimental tests in an antigravity field.
At the very beginning of the experiment, when the anti-gravity field was not turned on, an object with a wooden iron core was suspended in the middle of the water.
Afterwards, the anti-gravity field was turned on, and the object immediately floated to the water.
After several consecutive experiments, based on the experimental results, they determined that the antigravity field acts on mass rather than gravitational waves.
The principles are directly related to Wang Hao's research results.
Wang Hao’s research on photon architecture shows that anti-gravity fields will make particles inert. For example, the speed of light will decrease. However, particle inertia is not directly proportional to anti-gravity fields. Only fifty percent of the anti-gravity fields can slow down the speed of light.
Fifteen percent.
Therefore, even if the anti-gravity field can affect the buoyancy effect, it will certainly not be directly proportional to the weight reduction like an object.
When an object is suspended in a liquid, the forces it receives are naturally balanced. The formula can be drawn——
ρ liquid gV discharge = m substance g.
When the experiment is in an anti-gravity field, the buoyancy force is significantly greater than the effect of gravity, which naturally proves that the mass of the object has decreased.
The results of this simple experimental study are not 100% convincing, because there is no definite result on the impact of the antigravity field on buoyancy.
However, it is still very persuasive to a certain extent.
The antigravity team of the Planck Institute used a very simple experiment to prove that the antigravity field directly acts on the mass of an object, and the publication of the results will have a great impact.
Even though the photon structure results published by Wang Hao used data to construct an explanation that the effect of antigravity is the reduction of space squeezing effect, most scholars still prefer that the effect is the effect of gravitational waves.
Now the team from the Planck Institute has used an experiment to show that it is action and mass. To a certain extent, it has also confirmed the existence of the space squeeze effect and the annihilation force.
Muller from the Planck Institute team said in an interview, "It is at least very likely that the space squeezing effect, that is, the annihilation force, exists."
"The explanation of the annihilation force can perfectly explain the experiment, but the effect of gravitational waves does not even have a theory."
"We believe in experimental results, and often the simplest experiments are the most convincing."
After the results of this experiment were published, many people were surprised.
The reason why many scholars believe that antigravity fields act on gravitational waves is because they believe that mass will not change.
The current results show that the quality has been reduced, which seems to go against common sense.
Wang Hao couldn't help but sigh after seeing the new results, "It's a very simple experiment with very good results. I didn't expect that it could be verified so easily."
"There are still many geniuses in the world."
Wang Hao found that his previous thinking was too complicated, and he always linked the verification of antigravity field characteristics with very complicated microphysics.
The results of the Planck Institute now prove that simple mechanical research can also bring great help to the study of antigravity fields.
He Yi felt very annoyed. He felt that his team had such a good environment and was able to create more than 50% of the anti-gravity field.
The team at the Planck Institute can only create 15% of the antigravity field. Even for mechanical experiments, the effect is very poor.
To be continued...