When a decision made at a major meeting is named with the suffix "plan", it becomes very unusual.
In the history of American, there are several very famous plans.
The most famous of these is the Manhattan Project.
In June 1942, Amrican implemented a plan to use nuclear fission reactions to develop an atomic bomb, also known as the Manhattan Project.
This project has gathered the largest and best team of scientists, including Einstein, Fermi, Bohr, Feynman, von Neumann, Wu Jianxiong, Oppenheimer, Rabi, Lawrence, etc. , countless scientists participated in the Manhattan Project.
According to statistics, the Manhattan Project required more than 2,000 civilian personnel, more than 2,000 military scientists, and more than 1,000 famous scientists from various countries.
The total number of people planned to mobilize exceeds 100,000.
The entire plan took 3 years to complete and cost more than 2 billion US dollars. It finally successfully carried out the world's first nuclear explosion and created two practical atomic bombs according to the plan.
Two billion U.S. dollars may not sound like much, but remember, that was in the 1940s.
At that time, 1 US dollar could buy 170 kilograms of rice or 1 gram of gold. You can imagine how huge 2 billion US dollars was.
In addition, the most famous one is the Marshall Plan.
It was after the end of World War II. Marshall was a high-ranking official of Amerikan. He came to the famous Harvard University to give a speech and talked about being ready to rebuild O continent.
However, Marshall did not go into too much detail. He just said that AmeriCorps would provide money to help Continent 0 in order to develop Continent O.
Marshall said it to 0 continent.
Several major continental media broadcast the entire speech. At that time, the situation in the continent was very bad. The war caused the continent to lose its economy. Many people could not live their lives. There were workers' movements everywhere.
The Marshall Plan was an extremely successful strategic plan.
While helping West 0 and other regions, Amrican has greatly expanded its economic, military and other control.
Now Amerikan's top management has decided to formulate the 'Groom Lake Plan', which is a state-supported plan to invest in one-way technology research and development.
The reason for making a "plan" is because the investment will be very huge. Groom Lake is a place name less than 100 kilometers away from the bustling casino city of Las Vegas. The desolate area surrounding the lake bed is a famous military restricted area.
It also has another name - Area 51.
"The Groom Lake Project' is to establish a new large-scale laboratory in the desolate area surrounding Groom Lake, specifically for the study of annihilation force fields and related supporting plans.
At the same time, a large number of top scientists are invited to participate, and other university research institutions, large experimental laboratories, and large enterprises are allowed to cooperate in research.
In short, allocate sufficient funds and gather a large number of top talents to jointly research annihilation field technology.
American's senior executives believe that as long as they pay enough attention, they will definitely be able to surpass the flower growers and the anti-gravity research center in technology.
Because their investment is greater.
They have more and better scientists.
With so many top scientists, no matter how much funding they have, can't they be as good as an antigravity research center or Wang Hao?
...
Ameriken's top management has only drafted a plan, and it will definitely take a long time for the plan to be approved, detailed demonstrated, and then officially implemented.
But there is no doubt that they have given it absolute attention. Wang Hao didn't care about other countries or institutions. He didn't even have the concept of competition for the time being, because the Antigravity Behavior Research Center had been leading the research.
The International Annihilation Theory Organization has also created a strong annihilation force field, but the field strength is obviously too low to be called a competitor.
Plus, they have new technology.
The DC superconductor creates a strong annihilation force field, which is much more efficient than the AC superposition force field.
They are no longer on the same starting line.
Of course, having more advanced technology does not mean that you can sit back and reap the benefits. Technological competition means sailing against the current, and failing to advance will lead to retreat.
Therefore, Wang Hao is still thinking about the issue of technological improvement.
He feels that the next step is to start from the foundation of the annihilation field generation technology, that is, to develop new superconducting materials.
There is good news today.
Jieli Lithium, a large domestic lithium battery manufacturing company, was the first to use magnetized lithium element compound materials to create a lithium battery.
The R&D team of Jieli Lithium Industry reported performance test data, showing that the performance of the newly manufactured lithium battery is more than twice that of conventional batteries.
There are two important indicators for the performance of lithium batteries, one is the storage capacity and the other is the effective output power.
The power storage of the new lithium battery has been increased by 2.4 times, and the effective output power has been increased by 1.5 times. Other data, such as service life, are still in the testing process.
According to the existing data, the service life will also be slightly improved.
While this news is exciting, it also makes the formation of new companies around the manufacturing of first-order materials much smoother.
The formation of a new company requires products.
First-order iron is only one of them, but it is not the main one for the time being. The manufacturing speed in kilograms can only be supplied to scientific research units for the time being, which is far from meeting the market demand.
Magnetized lithium elemental materials are different.
The magnetized lithium element material only needs to pass through a strong annihilation force field and then undergo degaussing treatment. The manufacturing speed will be very fast and it can be put into the market directly.
Once the new company has products put into the market, it can continuously create profits.
On this day, Wang Hao went to the capital to attend a meeting of the science and technology department. The meeting discussed two points, one was the formation of a new company, and the other was the research issue of the annihilation force field.
Wang Hao is concerned about two points. One is the funding of the annihilation force field.
Funding is so important.
The Annihilation Field Experiment Team is very expensive. It can easily spend hundreds of millions of dollars on average every month. When focusing on a single research, the rate of burning money will increase several times, so it must have far-reaching and continuous financial support.
So when it came to the issue of forming a new company, Wang Hao directly proposed that the profits attributed to the new company should be invested in the annihilation field experimental team.
The proposal was quickly passed.
One is that the new company has just been prepared to be established, and the division of interests is not yet fixed. Of course, it must listen to the suggestions of the technical experimental group.
The second is that the research of the Annihilation Force Field Experimental Group is very important, and it is an important guarantee for the research and development of Annihilation Technology and the technological improvement of new companies.
The meeting finally decided that 20% of the profits every year would be provided to the annihilation force field experimental team and other related research.
In this way, the Annihilation Force Field Experimental Team no longer has to worry about funding issues, and may even become the richest scientific research institution in the future.
On the topic of annihilation technology research, Wang Hao also expressed his thoughts, "I think a new experimental group should be established to study superconducting materials that support the creation of antigravity and strong annihilation force fields."
"The high-pressure hybrid materials used by our experimental group have not been improved for a long time."
"This is a big problem."...
Superconducting materials are indeed very important.
Wang Hao believed that superconducting materials were the key to annihilation field technology. After returning to Xihai University, he also began research on superconducting materials.
His research is not to create superconducting materials, but to re-examine the semi-topological theory of superconducting from the bottom up.
When a brand new element is discovered, it can lead to a variety of new questions. The first-order iron element and the first-order lithium element bring about new 'superconducting theory adaptability' issues.
In the superconducting semitopological theory, the core is a basic formula
, you can solve for the superconducting transition temperature of a single element by inputting various data of the elements.
In addition, the superconducting transition temperature of the two-element combination can also be obtained through complex calculations.
If you go deeper, the difficulty of three elements and four elements will increase beyond exponential levels, and it will be very, very complicated to solve.
This basic formula also made the superconducting semitopological theory quickly recognized by the international physics community and became the most important theoretical basis for the study of superconductivity.
However, the emergence of first-order iron and first-order lithium has made the superconducting semi-topological theory inapplicable.
For example, first-order iron elements and conventional iron elements have the same protons, seeds, electrons and other properties. The critical temperature values obtained by bringing in the same data and solving the problems are naturally exactly the same.
Birkar analyzed, "This is probably because the electrons of the element transition to form a stable state, which is different from the elements in the conventional annihilation force environment."
"The relationship between electrons and nuclei differs in strength."
The fields of superconducting semitopological theory and annihilation theory are different, so Wang Hao found another team, including Bill Carr, Lin Bohan, Zhang He, Ding Zhiqiang and Luo Dayong.
Among them, Bill Carr, Lin Bohan and Luo Dayong were all involved in the research of superconducting semitopological theory.
Ding Zhiqiang’s main direction is also algebraic geometry.
Zhang He performed outstandingly in the theoretical calculation team engaged in superconducting elements. He still served as the team leader of the calculation team, and also held the position of deputy director, becoming the number two person in the calculation team.
The problem they hope to solve now is how to incorporate first-order elements into superconducting semitopological theory.
Several people expressed their opinions, "I think we can make corrections to several constants based on the experimental results of superconducting testing."
"This is impossible. Now there are only first-order iron and first-order lithium. There are few experiments and little data."
"Is there a possibility? To combine first-order iron with existing elements and transform the data?" Ding Zhiqiang put forward a strange point of view.
This idea sounds a bit bizarre.
Others thought about it carefully and found that there is indeed some truth. If they can find elements similar to the superconducting properties of first-order iron, or convert them into specific data based on their properties, they can be substituted into superconducting semiconducting materials. in topological theory.
In the end, Wang Hao shook his head, "The difference is too big."
"The closest thing to the first-order iron superconducting transition temperature is mercury, but there is no relationship at all in terms of other properties of the two."
"Even if it's just a transformation of the data, there are so many variables that it's simply impossible."
The research is currently unable to find a direction.
Wang Hao also gave others time to think, while he continued to study the relationship between the superconducting properties of first-order iron and first-order lithium.
The Superconducting Materials Laboratory has long begun research on the superconducting properties of first-order elements.
They have determined the superconducting transition temperatures of first-order iron and first-order lithium, as well as the transition temperatures of several iron-based superconducting materials made from first-order iron.
Two of the iron-based superconducting materials have very weird transition temperature data. Not only do their transition temperatures not increase, but they decrease a lot.
This is where the problem lies.
The transition temperature of the first-order iron element has been greatly increased. In addition, the transition temperatures of the two iron-based superconducting materials initially measured have increased. Many people have a fixed impression-as long as the iron is replaced by a The material's transformation temperature will rise.
As a result, they found a decline.
Wang Hao also asked the research team to focus on these two materials, and also asked the Antigravity Properties Research Center to measure the antigravity properties of the two iron-based superconducting materials.
He simply went to the Antigravity Behavior Research Center.
When I arrived in front of the experimental group, I saw He Yi walking out, waving and shouting, "Academician Wang, you came just in time!"
Wang Hao walked over.
He Yi followed him in and said, "We just completed the measurement of one of the materials, and the results were a bit special. I was about to go
Tell you. "
Wang Hao suddenly became interested, "Tell me about it."
"The conventional transition temperature of this superconducting material is 73K. If it is replaced with first-order iron, the transition temperature is only 65K."
"We have done anti-gravity tests before, and the highest field strength was only 0.96 (4%). However, when it was around 139K, the anti-gravity phenomenon was discovered in the experiment. It was not until 100K that it was determined and the measured value was 0.2%. "
"We thought we had made a major discovery, but it turned out to be 71K, and the value increased to 0.3%."
He Yi felt a little regretful, "64K, in the superconducting state, is only 0.4%, which is really too low..."
His voice changed as he spoke, and he smiled, "Although we failed to discover that kind of super material, it is still a very important discovery, right?"
Wang Hao thought about it carefully, "The transition temperature is only 65K, but the antigravity phenomenon can be found above 100K..."
He smiled bitterly, "Studying the applicability of superconducting semi-topological theory to first-order iron is already confusing enough. I still have no clue. Your discovery has made the research more complicated."
"What a mess!"
"The original theories have been overturned, and the original experimental results have completely lost their meaning..."
"Alas~"
He sighed, thought carefully and muttered, "However, the experimental results are confusing...it may also be a significant progress!"
