The meeting continued.
Wang Hao's speech was only a general introduction to dense material technology, future elements and discovered first-order elements.
What follows is a detailed introduction.
He Yi, Xiang Qiansheng, Wang Jinlu and others made speeches respectively.
They gave detailed explanations respectively, including the improvement of material performance by dense material technology, including the physical properties of beta iron elements in the future, including the properties of several first-order a elements, etc.
Everyone in the venue was listening attentively. At the same time, they also felt very incredible. What followed was a strong desire for knowledge and abundant confidence.
The dense material technology introduced to Qian Sheng can directly improve the physical properties of materials.
He gave the example of 'pure gold' to illustrate.
Scholars also have an understanding of technology. Simply put, dense material technology can directly improve the physical properties of materials, including density, melting point, boiling point, toughness, etc.
Such technology will produce qualitative progress in materials science.
For example, nickel-iron alloy.
Nickel-iron alloy is the fan blade material of aerospace engines. The melting point of the highest-end nickel-iron alloy can exceed 1450 degrees Celsius.
Many aerospace materials-related institutions will study the manufacturing process and technology of nickel-iron alloys, but the general results only increase the melting point by a few degrees, and the service life and toughness are correspondingly improved.
That kind of improvement is a step forward on the hundred-foot high pole. The original ‘100’ can only be improved to ‘101’.
Dense materials technology is different.
When dense material technology is used, the density, melting point and toughness of the material can be greatly improved, from '100' to '120' or '130'. Putting it on a single material is equivalent to a leapfrog Decades of progress.
With such technology, many material difficulties will be easily solved.
The design of nuclear fusion equipment is very difficult, and the demand for materials is also very high. However, in fact, so many scholars have demonstrated nuclear fusion technology, which shows that nuclear fusion is theoretically possible.
Although the demand for materials is high, it is not despairingly high.
For example, inner layer insulation material.
During the nuclear fusion reaction, the internal temperature can reach hundreds of millions of degrees Celsius, but the melting point requirement of the memory insulation material is not as high as "tens of millions of degrees Celsius".
That is impossible.
The material with the highest melting point today is only about 5,000 degrees Celsius.
The reason lies in the density. The explosion temperature of the nuclear fusion reaction is very high, but the inner explosion temperature and the actual temperature are two different things.
In weather forecasts, temperatures are divided into normal temperatures and perceived temperatures.
Conventional temperature refers to the degree of heating, which can be understood as the activity of molecules. Needless to say, somatosensory temperature is the actual feeling of the human body.
In general laboratories, temperature refers to the activity of particles.
At ultra-high temperatures of hundreds of millions of degrees Celsius, particles are heated to an ionic state, and only extremely active ionic states can produce nuclear fusion reactions.
But the inner layer of insulation material is not designed to withstand extremely high temperatures.
The reason is simple: density.
To give an everyday example, the temperature of water vapor can exceed 100 degrees Celsius, but your arm will not necessarily be burned if it passes through the water vapor.
It would be different if it were boiled water.
This is because the density of water vapor is low, and the density of water is high, so the physical sensation it brings to people is not on the same level.
The thermal insulation material of the nuclear fusion device is much higher than the ionic material where the fusion reaction occurs inside, so naturally it cannot withstand high temperatures of hundreds of millions of degrees Celsius.
Of course, the temperature that insulation materials can withstand is not low either.
However, the inner layer also has a thin layer of strong annihilation force field with absorptive capacity, so the melting point requirement of the inner layer of insulation material is not that high.
In fact, the melting point of insulation materials is not a big problem. China has already manufactured artificial solar devices. When a fusion reaction occurs in the device, it can reach ultra-high temperatures of more than 100 million degrees Celsius.
Without the assistance of a thin layer of strong annihilation force field, the inner material can withstand it.
The key to the material problem is still to cope with neutron impact and whether it can ensure stable performance in extremely harsh environments for a long time.
Material life is a big issue.
The outer material is relatively good, but it is very complicated to replace the inner material.
For example, rubber.
Composite rubber has many benefits for sealing, but the life of the rubber is a big problem, and it is easy to dry out and crack with continued use.
This is the problem that needs to be solved.
…
After the meeting.
The scholars did not leave for a long time, and they were all discussing continuously.
Everyone was very surprised and excited.
Many people know that Wang Hao's team's research on strong annihilation force fields must have many undisclosed technologies, but they never expected that there would be so many discoveries in just materials.
The Antigravity Behavior Research Center is the scientific research institution that has attracted the most attention in the world in recent years.
Many media reports will focus on the strong annihilation field technology mastered by the Antigravity Behavior Research Center. Therefore, many people judge that the strong annihilation field technology of Wang Hao's team has reached a bottleneck of rapid progress.
This can be seen from the discovery of first-order elements.
The Antigravity Properties Research Center discovered iron and lithium, and was soon able to mass-produce first-order iron. Later, the first-order carbon element was discovered.
Then, it stopped.
After the first-order carbon element was discovered, Annihilation Technology did not release any relevant news, indicating that it was impossible to mass-produce magnetized carbon materials.
The technical judgment of institutions and scholars on Wang Hao's team is that it can create a strong annihilation force field with a maximum power of about '8.3 times'.
Now it seems that all judgments are wrong.
So many first-order elements have been discovered, and the strong annihilation force field created is even higher than the '8.3 magnification'. They still have the energy to research a brand-new material technology, which shows that the technical level they master has far exceeded ordinary people, even
The imagination of scholars.
At the same time, many scholars are also talking about first-order hydrogen.
This chapter is not over, please click on the next page to continue reading! First-order hydrogen is the most popular upgraded element because hydrogen is a gas element. In addition, the hydrogen isotope ‘deuterium’ is a material for nuclear fusion reactions.
Then here comes the problem.
"Is it possible to produce first-order deuterium?"
"If first-order deuterium is used as the raw material, will the reaction be more intense and require lower temperatures?"
"The activity of upgraded elements will increase. What is certain for the time being is that if we use first-order deuterium and first-order tritium as raw materials, we will definitely be able to create an astonishingly powerful hydrogen bomb..."
…
After the meeting, Wang Hao left and returned to Xihai University.
His job is to participate in conferences and announce technologies and findings. The announcement is only to the scholars attending the conference, rather than officially releasing information to the outside world.
Of course, after the official release, confidentiality will definitely be challenged.
But it's not a big deal.
They are doing material research and development for the design of nuclear fusion devices, not to create weapons that threaten the world. The reason why their technology and discoveries are not made public is mainly due to the confidentiality issue of f-rays.
Material research needs to be done by professionals.
The Annihilation Force Field Experiment Team and the Annihilation Technology Company's technical department will cooperate with other institutions' research, and the specific work will be left to Xiang Qiansheng, He Yi, Wang Jinlu and others.
Wang Hao returned to the Mason Number Laboratory, and he was still more interested in theory.
Time theory.
He hopes to understand the principle.
Although most outsiders do not approve of the theory of time, Wang Hao is certain that his research is correct.
So here comes the question--
How does time exist independently of movement?
Is time a dimension? An electromagnetic wave? Or a space fluctuation?
To be continued...