Crossing rivers and demolishing bridges, concealing the truth and crossing seas, building plank roads openly and concealing old warehouses, and removing fuel from the bottom of the cauldron...
A lot of classic idioms can be applied to Parsons' behavior.
If he were to stand on an upright standpoint, he would definitely be labeled as "exceptionally witty," but if he were to stand on any other standpoint, he would be labeled as "despicable and shameless."
In fact, many things are like this, and different opinions will naturally lead to different evaluations.
For example, Zhuge Liang, the famous Shu military commander, can definitely be described as resourceful and witty, but from the perspective of the Wei state, you can say that he is cunning, cunning, scheming, and even despicable.
exactly.
A large group of string theory scholars are all on the opposite side.
In the face of a despicable and shameless villain, even if they all consider themselves to be gentle people, it would be terrible for the gentle people to break out.
So Parsons was hospitalized.
The good news is that all he suffered were external injuries, but several parts of his body were wrapped in white cloth, making him look pitiful on the outside.
Parsons was lying in bed reflecting.
He felt that he was very wronged, because he also believed that he had classified the annihilation system into the category of string theory. Because of this, the paper would be expanded in the future and would have a 9+1 dimensional logic.
It is precisely because of this that he readily accepted the invitation to attend the party in the small town of Princeton.
The result was that the wolf fell into the tiger's mouth...
After this incident, Parsons knew that he had become an absolute traitor to string theory. Not only did he turn to study annihilation theory and achieve results in the research of annihilation theory, he also inadvertently cheated him.
Scholars who learned about Edward Witten and string theory.
Many media have reported the content, and string theory scholars feel that they have been tricked, not to mention the person directly related to the incident, Edward Witten.
"I became Poisson..."
"No, it should be further than Poisson..."
In the history of the development of microphysics, scientists have been arguing endlessly about whether light is a particle or a wave. Poisson is a scientist who insists on the particle theory of light. He insists that light is composed of particles.
Occasionally, Poisson calculated a problem - when monochromatic light shines on a small circular plate or bead of appropriate diameter, a ring-like pattern of identical colors will appear on the subsequent light screen.
The diffraction fringes of the central circle, and a very small bright spot will appear at the center of all concentric circles.
This is the Poisson spot.
Poisson hoped to use this conclusion to overturn the wave theory of light, and then a dramatic scene occurred. The Poisson bright spot became strong evidence of the wave nature of light.
At that time, Poisson was labeled a "traitor" by the particle school, and his reputation among the particle school could be said to be "stinky street."
Now Parsons feels that his experience is very similar to that of Poisson, and Poisson just completed a study, and he also made a large group of string theorists lose face.
So he goes one step further than Poisson.
"It seems that from now on I can only stand firmly on the side of the annihilation theory..."
Parsons thought depressedly that the purpose of his research was just to make a living. Research could get higher funding and make life easier.
This is his purpose.
As a result, he was forced to stand, which made him feel very depressed. He couldn't help but think of his former friend, Paul Phil Jones.
Now there are two "traitors" in the string theory school, one is him and the other is Paul Phil-Jones.
They should contact them more in the future!
In the current international physics community, string theory and annihilation theory have become opposing theories.
Although it is not a direct opposition, the situation is similar, a bit like the opposition between the particle school and the wave school in the past.
The advantage of string theory is that the mathematical system has been developed for decades, has rich accumulation and systematic research, and has been applied in many theories.
The advantage of annihilation theory is that it predicts particle collision experiments, and it is more easily accepted by being linked to the experimental results.
Parsons' research contribution is that he developed another direction of annihilation theory - based on the definition of annihilation system, he used the definition of annihilation system as a basis to demonstrate some focus physical issues and develop theoretically related directions.
Paul Phil-Jones is studying the field of combining quantum physics.
As the founder of annihilation theory, Wang Hao is very pleased with Parsons' research. He just hopes to see annihilation theory be applied in research in various directions, and more scholars will participate in research.
"Parsons, what a genius!"
Wang Hao couldn't help but sigh that the development of a physical theory cannot be completed by one scholar, but requires the participation of many scholars.
Wang Hao's main research direction is different from that of Parsons and Paul Phil-Jones. He is studying the mathematical framework of annihilation theory.
The mathematical framework is mainly the underlying definition, which lays the foundation for the annihilation theory.
Research based on the basics can be completed by other scholars.
At the same time, Wang Hao gained something from Parsons' research. He found that Parsons's explanation of "high-dimensional problems" was very interesting.
Wang Hao's published results did not explain what high dimensions are, but his own understanding is that "causal relationship" is the formation of three microscopic forces under the influence of space extrusion.
Parsons's understanding is a real high dimension, such as four dimensions, five dimensions, or higher dimensions. His mathematical explanation of this and the method of studying the definition made Wang Hao feel that
It also seems to be very useful in the study of semi-topological microscopic morphology.
Multi-elements constitute a conductor, and the semi-topological microscopic morphology and geometric composition inside the conductive state are extremely complex. They may really exceed the limit of dimensions, and it is almost impossible to completely decipher them.
Wang Hao's research on microscopic morphology is stuck here. He can only do part of the research instead of expressing it as a whole.
Parsons' research techniques inspired him. In many cases, the research on microphysics does not need to be fully expressed. It can also be based on the direction of theoretical physics and combined with known phenomena to give reasonable explanations.
"So, we can also use speculation to shape a mathematical framework and express the divisions with equations to give an overall description..."
Wang Hao thought, "We can start from known materials and use a large amount of measured data to create a 'theoretical semi-topological microscopic form.'"
"So let's start with '1002,' 1002, which is the superconducting material experimental group. The superconducting material developed has a superconducting critical temperature of 132K.
Expression is made up of seven elements.
If the semi-topological micromorphological shaping of '1002' can be completed, even if it is only theoretically shaped, it will be very valuable for the study of the theoretical mechanism of superconductivity and the development of semi-topological theory.
This research process is of course not easy. The semi-topological microscopic morphology formed by macromolecules composed of seven elements and fifteen types of atoms is so complex that it is even too complex to be imagined in the mind.
He can only infer the determined microscopic morphological structure based on the known material properties, including the specific atomic composition, anti-gravity efficiency, and the relationship between element combinations, and then conduct a 'theoretical' analysis.
Wang Hao is devoted to the theoretical framework of semi-topological micromorphology of complex materials.
This work requires a lot of brain cells, and the research may not be fruitful.
Therefore, he was not in a hurry to complete the research, but spent his leisurely work life every day, only thinking about it when he had some ideas.
On this day, Deng Huanshan was specially invited to give an experimental work report. Their experimental research discovered three new materials with superconducting critical temperatures of 79K, 81K and 93K respectively.
The superconducting critical temperatures of the three new materials do not exceed 100 K. Naturally, they are not considered to be any major discoveries. They only conducted tests on the new materials.
The experimental group’s naming rules for the new materials developed
Yes, for materials that are determined to be valuable, the naming code starts with ‘C’; for materials that are of little value, the naming code starts with ‘CA’.
The three new materials are named ‘CA003, ‘CA004, and ‘CA005,’.
"CA005 is very interesting." Deng Huanshan said in the report, "We experimentally produced some materials and conducted anti-gravity tests. The AC field values ​​of 3 and 4 were both between 25 and 30, while CA005 reached 34.
"
"Thirty-four percent?" Wang Hao frowned slightly upon hearing this.
"right."
Deng Huanshan finished speaking affirmatively, shook his head and said, "But it's useless. It's still too early to talk about anti-gravity now, and thirty-four..."
Wang Hao interrupted and continued, "It's a very high value!"
He said it very seriously.
Deng Huanshan also realized Wang Hao's seriousness and suddenly became much more serious.
Wang Hao did not explain, but immediately handed over the work, "You prepare more CA005. I need to study this material carefully."
"good!"
Deng Huanshan didn't know what Wang Hao was going to do, but he still nodded in agreement seriously.
Wang Hao attaches great importance to 'CA005. When he heard the value of 34%, he felt it was very unusual.
Deng Huanshan did not understand the principle of the AC gravity experiment, but he understood the AC gravity experiment very clearly. They had previously increased the AC gravity field strength, that is, the anti-gravity strength, to more than 40%.
To be continued...