From University Lecturer to Chief Academician

The gains from the internal discussions were very great.

One is to improve some theoretical content of the force field. Helen's research is very detailed, and some of them have also returned correct content.

Some of her research and analysis of force field changes are remarkable.

But the most important achievement came from Ding Zhiqiang. From a logical point of view, Ding Zhiqiang believed that a force field appeared between atoms, which made the gravitational force and electromagnetic force reach a balance.

The special materials produced by the experiment are all radioactive.

Wang Hao deduced from this that there is a certain balance point between the characteristics of the material and the strength of the annihilation force field, so that the manufactured dense material is no longer radioactive.

This is a recommendation based on analysis, and also related to the correct idea of ​​system feedback.

So Wang Hao immediately explained the relevant experimental research, and even applied for a separate project called "Research on Manufacturing Technology of De-radiation Dense Materials".

Dense material manufacturing technology is now available.

To put it simply, it is to melt the metal and place it in a strong annihilation force field, and at the same time apply a certain external force to compress it, and then let the metal cool and solidify naturally.

The next step in the research is 'deradiation'.

'De-radiation' is to find the balance point between the material properties and the strength of the annihilation force field. There are two ways to help the research, one is to continuously reduce the strength of the annihilation force field.

The second is to replace the material for research.

The difficulty of the former method is very high. Fortunately, the annihilation force field experiment group has several generating devices, and the strength varies from 6.0 times to 8.3 times.

"If the intensity multiplier is close to the equilibrium point, theoretically, the radiation intensity will decrease."

"At the same time, it is necessary to conduct research on other metal materials and compare the data."

"In this way, we can quickly prove whether the theory is correct, and we can think from the direction of application to develop some practical dense materials."

Wang Hao said to Xiang Qiansheng, "However, it is enough for our experimental group to do a research. We mainly focus on theory and science. In terms of technology, we will hand it over to the technical department of Annihilation Technology Company or other institutions for research. .”

Xiang Qiansheng took over the research.

Xiang Qiansheng is not solely responsible for the research, but also requires the cooperation of the technical department of Annihilation Technology Company, and part of the research will also be carried out at the Aeronautical Research Institute.

This is because it involves material research.

The annihilation force field experiment group is not suitable for doing research on materials alone. There are some shortages of equipment and personnel. They can only provide the annihilation force field device, responsible for the main experiment part, and keep track of the research progress. Other departments must be responsible for other aspects.

When conducting research on dense material technology, the Annihilation Force Field Experimental Group also bears the name of the Antigravity Behavior Research Center, and regularly releases new experimental results.

What they disclosed this time is a new discovery, that is, the production of radioactive first-order iron elements.

"We created a new type of first-order iron."

"This kind of first-order iron, which we call 'dense first-order iron', is made of pure iron with a content of more than 99.99%, and its density, toughness, and strength are all improved compared with conventional first-order iron."

"At the same time, dense first-order iron has radioactive characteristics..."

"Our research suggests that dense first-order iron is likely to be the manifestation of conventional iron elements when the conventional annihilation force field rises to eight times the rate of evolution after tens of billions of years..."

"This research discovery, to a certain extent, confirms the theory that the behavior of elements changes with the rise of the conventional annihilation force field in the universe."

"..."

"Annihilation Physics and Theory" published the latest experimental findings, which also attracted great attention from the international academic community.

When the research was officially published, the famous physicist Hodge Enske immediately said, "If (the research) is true, it is really remarkable."

""The Development of the Universe and the Properties of Elements" is the theory of evolution in physics. This theory holds that the properties of elements are constantly changing along with the development of the universe."

"Now the discovery of radioactive first-order iron is tantamount to verifying the theory of evolution in the physics world..."

Many scholars also thought of another problem.

The research results completed by Wang Hao, the theory about the annihilation position and the development of the universe, the most notable and influential one is "The Theory of Cosmic Expansion".

According to the theory of cosmic inflation, supermassive black holes may have existed for an infinite number of times.

The development of the universe is accompanied by expansion and contraction. In the process of alternating expansion and contraction, black holes may not be destroyed. Some black holes may have several cycles, or even "countless cycles".

The black hole is the aggregate of the strong annihilation force field and the upgraded particles.

So is there a possibility that there are countless unimaginable high-order elemental substances in the black hole? Dense first-order iron may also exist in it.

In other words, dense first-order iron may exist in the universe.

Scholars are talking about another point, which is the significance of the discovery of dense first-order iron itself. "From stable elements to radioactive elements, it is the first time that mankind has achieved a breakthrough in changing the behavior of elements."

"Then in turn, radioactive elements can also be used to produce stable elements."

Many scholars are interested in this.

It's a pity that they can only conduct an analysis, and they can't participate in the experimental research at all, because the high-magnification and strong annihilation force field technology is only possessed by the Antigravity Behavior Research Center.

Whenever the Antigravity Behavior Research Center discloses some research results of the annihilation force field, many people will think of the other two institutions at the same time——

International Annihilation Theory Organization and the Groom Lake Project project team.

The International Annihilation Theory Organization is relatively better, because their technology research is advancing steadily, and they are researching step by step, so that people know that they will be able to master high-end technology sooner or later.

The future seems far away, but at least we can see it.

The Groom Lake plan is different.

They have not published any impressive results until now, and it seems that there is no wave of spending tens of billions of dollars, which makes people feel very dissatisfied.

In fact, research related to the Groom Lake project is very busy.

Under the leadership of Gamow-Shapley, a large group of scholars involved in the project devoted most of their time to the study of the antigravity properties of materials.

Recently, their research has progressed smoothly and achieved remarkable results.

This is also related to the large-scale sale of first-order iron. With enough first-order iron obtained, many superconducting-related companies have begun to research first-order iron-based superconducting materials.

The activity of first-order iron elements is very strong, coupled with the accumulation of technology in the past few years, it is easy to study various first-order iron-based superconducting materials.

In this way, Gamow-Shapley's experimental group devoted all their energies to the experiment of anti-gravity characteristics.

Massive funds, massive experiments...

The results are naturally indispensable.

Their latest achievement is the discovery of a new type of first-order iron-based superconducting material, which can achieve an antigravity field strength of 6.79% at a temperature higher than the transition temperature of 48K.

This is the highest figure obtained since the beginning of the research program.

Gamow-Shapley was still dissatisfied with this data, and he hoped to directly produce a first-order iron-based superconducting material with an antigravity field strength higher than 30%.

Now it is only 6.79%, which is relatively low.

After feeling the huge pressure of public opinion from the outside world, Gamow-Shapley decided to make the research results public as soon as possible, and published them in the "Science" magazine's newsletter report.

...

"New achievements of the Groom Lake Project, higher than 48K to achieve anti-gravity super materials!"

"The transition temperature is 139K, and the antigravity field strength is 6.79%. The new material has reached the highest among first-order iron-based superconducting materials!"

"Shapley: Our goal is to develop a material with a strength of more than 30 points to replace the high-pressure mixed material to create a strong annihilation force field!"

"Shapley: This is just the beginning!"

After the Groom Lake project team released new results, a large number of media reported on it, and Gamow-Shapley also publicly accepted interviews, saying that their research is progressing steadily.

After talking about a series of studies, he said with certainty, "Now we are very close to creating a high-intensity annihilation force field."

A series of reports made a big impact.

Many people have paid attention to the Groom Lake project again, but most scholars have reservations. Gamow-Shapley said a lot of big things before, and up to now, he has only discovered a method that can be used at 187K , to create the anti-gravity field material.

This is still far from creating a strong annihilation force field.

The materials released by the Groom Lake Project have not received much attention at all, and most scholars believe that they are only "transitional materials".

"If you want to replace high-pressure mixed materials, the strength of the anti-gravity field produced cannot be lower than 25%."

"6.79% and 25%, the gap is still very large."

"This numerical gap is still far away from achieving the goal. Maybe they should change their thinking and study technology, not just materials?"

The F-ray experimental group didn't see it that way.

Recently, the f-ray experiment team has been very busy. The nuclear reactor built in their new equipment has been operating normally for more than a month.

At this time, the f-ray excitation experiment can be started.

Wang Hao also came to the experimental group. After he arrived in the experimental group, he knew the news published by "Science" magazine, and he was very surprised immediately, "Shapley, you are really good."

"Maybe it's luck."

Liu Yunli holds a different view, "And they have invested tens of billions of dollars, such a huge investment, and so many cooperative institutions."

He said and shook his head, "The most important thing is that they don't seem to pay much attention to this achievement, and they published it directly. They think it's just a transition..."

Liu Yunli laughed at everything he said.

The first-order iron-based superconducting materials used in new equipment now have only about 6.5% of the antigravity field strength excited initially.

They used micron-scale granular material manufacturing technology, coupled with the compression of the helical magnetic field and the energy support of the built-in nuclear reactor, to create a thin layer of high-intensity annihilation force field, and prepare to excite high-intensity F-rays.

Simply put, the material developed by Shapley has surpassed the material used in the new equipment of the F-ray experimental group in terms of performance.

"Indeed it is."

Wang Hao laughed, "I read reports that Shapley has developed materials with an anti-gravity strength exceeding 30 points..."

He kept shaking his head as he spoke.

That is simply impossible.

First-order iron is used to create an annihilation force field, and the intensity of the excitation is naturally limited, mainly due to the influence of special phenomena.

If you want to use first-order iron to excite an anti-gravity field with a strength exceeding 30%, you can only use 'dense first-order iron'.

'Dense first-order iron' is no longer restricted by peculiar phenomena.

In this regard, they have only just begun to study.

In addition, it is impossible for them to sell the 'dense first-order iron' abroad, and it can only be used for research and development within the annihilation force field experiment group.

Shapley has no basic materials in his hands, and his research is simply a grassroots without roots. It is not easy to make progress.

The problem is, they don't know the right direction.

They clearly researched a very remarkable material, but they didn't know what was so great at all, and they didn't even pay attention to it, and the results were released directly.

"There are treasure mountains in the sky without knowing it!"

Wang Hao sighed, "They don't know granular material technology, let alone DC anti-gravity, so they don't pay much attention to the materials they research."

Liu Yunli's eyes suddenly brightened, and he asked, "If they develop better materials, maybe we can cooperate with them in material technology?"

"That's not something we worry about."

Wang Hao shook his head with a smile.

Liu Yunli's approach sounds like he is cheating children. Children don't know the value of the things in their hands, and they may be able to 'cheat' away with a piece of candy.

Of course, he has no objection to this approach.

This is the advantage of mastering high-end theoretical techniques.

Over the past many years, the precious resources held by the country have also been "cheat" away by foreign countries in this way.

For example, rare earths.

In the beginning, the sale of rare earths could be described as "buy half, give half away", because there is no technology to use rare earths in China, and the high value of rare earths is not understood.

When a foreign company asks for a price, it sells it directly in large quantities.

The two talked about the report of the Lower Groom Lake Project, and also talked about the recent research issues. Liu Yunli is responsible for many research directions, including the "fan-shaped F-ray excitation technology".

"Three times, all failed."

Liu Yunli shook his head depressedly, "We opened two adjacent ports, but the force field was squeezed and escaped."

"It's still a matter of magnetic fields and energy."

Wang Hao thought for a while and said, "Not only is the built-in energy intensity not enough, but the internal spiral magnetic field needs to be re-demonstrated and designed."

"Two ports are not the same as one port."

"When two ports are opened, the fringe magnetic field is no longer in a circular distribution, which may cause inversion and repetition problems, wasting most of the field force..."

He analyzed it carefully, then shook his head and said, "It's better to carry out this experiment first. Only with built-in nuclear fusion support can the energy be sufficient."

"At that time, you can take your time to argue."

Now the f-ray excitation experiment is the most important.

The experiment has been prepared for a long time, mainly for the inspection of the device. It is necessary to ensure that all parts are running stably before the experiment starts.

This is mainly because of the built-in nuclear reactor.

As long as there is a slight error in the device, it may cause a huge experimental accident, and it must be stable before exciting the f-ray.

When the last test was over and relevant personnel reported the data, the stimulation experiment officially started.

Many people who participated in the experiment were very excited, because they knew that high-intensity f-rays would be excited immediately.

That's sure to pay off a lot.

Wang Hao did not directly participate in the experiment, he just stayed in the main experiment base, waiting for relevant personnel to report the results.

He was sitting in front of a computer, looking at the monitoring screen of the experimental device.

Everything is going smooth.

After Liao Jianguo yelled 'open the launch port', he waited for about three seconds before he saw a black light appear on the surveillance screen.

"It worked."

Wang Hao muttered to himself very flatly.

Soon someone reported excitedly, "Academician Wang, it's a success. We released F-rays, and the duration of the instant measurement is 0.913 seconds!"

"1.17 centimeters in diameter."

"The radiation intensity of the release port exceeds the measurement range (10 times ratio)..."

"..."