Li Qingye in Luzon is actually very aware of the salvage and research of B43.

It's just that he didn't interfere, but let his subordinates and professionals do it.

After all, Homo sapiens now has four control areas, and if he, the chairman, has to do everything himself, then he can't bear it even if he has a super brain.

Otherwise, why would he recruit troops?

When ornamental?

If you have subordinates, you have to let your subordinates work, and his core job is to control the general direction and scientific research, and there is no need to do specific things yourself.

At this time, he was working on nanotechnology, biological nanotechnology to be exact.

In fact, the structure of living organisms and organic materials, in the microscopic world, are a variety of nanostructures.

For example, silk, spider silk, abalone shells, etc., are typical nanostructured materials.

Li Qingye pays attention to this research, mainly because when he was researching biochips before, he developed cell directed development technology and biomineralization induction technology.

After the in-depth integration and improvement of these technologies, he has successively developed a series of new bionanomaterials.

Including the low-temperature glass and iron bamboo materials that were tested before, it is actually an attempt at this technology.

Recently, Li Qingye collected a special kind of submarine snail from the vicinity of the submarine hydrothermal vent in the Ceylon Ocean through a submarine, the scaly-legged snail.

From the genetic sequence of the snail foot, he discovered a special gene sequence that can enrich metal elements to form a nano-iron sulfide layer.

Through genetic recombination technology, Li Qingye combined some of the dominant genes in coral, scaly-legged snail, seabed hydrothermal vent bacteria, and metal ore bacteria to give birth to biological high manganese steel.

In a special cultivation pool in the laboratory.

A patch of coral is slowly growing.

Several experimental assistants pressed the drainage system of the cultivation tank, and the nutrient solution in the cultivation tank was immediately sucked dry, and then the automatic transport system was activated.

The wheels at the bottom of the cultivation pool began to drive slowly towards the elevator.

Through the elevator, you will be taken to the experimental area on the upper floor.

Here, the four sides of the nursery are opened, revealing layers of grayish-white corals, each 2 centimeters thick.

The emery waterjet quickly divides the layers of coral structure, and the last layer on top, because the transgenic polyps are still there, is put back into a new cultivation pond and sent to the experimental area below to continue cultivating.

There are 20 layers of coral structure cut, each layer is 2 cm thick, and the length and width are 100 cm.

These plates are fed into the acidolysis tank to break down the coral calcification layer on the surface of the coral plate, revealing the dark gray bio-high manganese steel plate inside.

The strength of this plate is ridiculously high, and thanks to its low-temperature synthesis, each lattice is nanoscale and neatly arranged.

Its strength is equivalent to 3.72 times that of ordinary high manganese steel, the hardness is 1.43 times, the corrosion resistance is 3.21 times, and the energy consumption is equivalent to about 23~27% of ordinary steel.

This strength, hardness, and corrosion resistance are more than enough as raw materials for precision equipment.

In addition to bio-high manganese steel, there are also bio-molybdenum steel and bio-titanium steel, the former is resistant to high temperature and wear, and the latter is lightweight, corrosion-resistant and highly bio-affinity.

In addition, the alloy material produced in this way has another advantage, that is, it can be molded in one time by reducing secondary processing.

Essentially, biosynthetic alloys are additively processed.

And now the finishing is generally subtractive processing.

The effect of these two processing methods is not the same, and the cost is also different.

As for who is superior and who is inferior, it depends on the technical level of both sides.

For example, the 3D printing technology of additive processing is currently difficult to compete with traditional subtractive processing in the field of metal processing.

However, Li Qingye's biosynthetic material technology is different, after all, ultra-precise growth at the nanometer level has been achieved, and the technology is obviously at a higher level.

Li Qingye with the help of his assistants.

A steel plate marked No. 53 is placed on the high-temperature test platform.

"Let's start heating up!"

"Yes, boss!" The assistant presses the switch.

Suddenly, on the high-temperature test platform, an electric heating system similar to an electric arc furnace began to fully heat this piece of steel plate.

Time slipped away minute by minute.

The heating temperature on the platform is also steadily rising.

500 degrees Celsius......

800 degrees Celsius......

1200 degrees Celsius......

But the steel plate showed no signs of melting.

It was not until the temperature was raised to 3736 degrees Celsius that the steel plate was slightly deformed, but it still did not melt.

The temperature was then raised to 5122 degrees Celsius again, at which point the steel plate finally melted, but not completely, and some of it was in a clump state, like viscous magma.

Finally, the temperature reached 5506 degrees Celsius, and the molten steel was like boiling water.

The assistant holds the biological plate and records this series of experimental data.

This was followed by repeated heating and cooling experiments at 500 degrees Celsius, 1000 degrees Celsius, 1500 degrees Celsius, and 2000 degrees Celsius.

Moreover, it is divided into a control group of whole heating, single-sided heating, and local heating.

This alloy is bio-nano-molybdenum-manganese steel.

However, this material is not an extreme high-temperature resistant material, and the real high-temperature resistant material still depends on the ceramic matrix composite.

In this regard, Li Qingye is also engaged in biosynthesis.

By adding a part of carbon, molybdenum and titanium, the bio-nano ceramics are formed, and there are currently some varieties that can grow bio-nanoceramics with a melting point of 5637 degrees Celsius and a boiling point of 5912 degrees Celsius.

Why does Li Qingye pay so much attention to the research and development of materials?

The reason is that the precision machining technology of Homo sapiens is very backward, let alone catching up with Europe and the United States, even if it is compared with Chinese enterprises, it is not comparable.

With the processing technology and processing equipment of the last century, no matter how powerful the supercomputer and engineer are, it is difficult for a clever woman to cook without rice.

Therefore, the material became the only choice for overtaking in corners.

As long as the materials are good enough, you can play the set of big bricks flying.

The engine isn't good enough, is it?

Directly on the ultra-high temperature deflagration.

Accuracy is not good?

Then hardness and strength to compensate.

Backward design?

Material hard piles.

It's like a chef cooking, the other party's cooking skills are very good, and they can turn decay into magic; Then I'll go straight to the top ingredients and cook them in the most simple way.

The advantage of Homo sapiens is the low-cost production of materials, these top materials can achieve the price of cabbage, even if the processing technology is not good, the effect is almost the same.

For example, some time ago, the development group in Honsavady purchased the old MiG-25 fighter production line from Sukhoi Airlines in Lucia through product exchange.

Sukhoi, which had taken over the MiG legacy, did not pay much attention to this old thing, and refurbished the mothballed production line and sold it to the Development Group in tears.

Homo sapiens previously purchased the MiG-25 production line through the vest in order to take a fancy to the stainless steel design of the MiG-25.

It's no joke.

Due to the use of a large amount of stainless steel, the weight of the MiG-25 is too large, resulting in very high fuel consumption, average range, and short engine life.

But this shortcoming, for Homo sapiens, is not a problem at all.

Now the various new materials developed by Li Qingye, just take out a few of them, and you can make the MiG-25 reborn.

When the time comes, the upgraded MiG-25 is estimated to be no worse than any Rafale among the world's active fighters.

Thank you for your support (ω'), ask for subscriptions, collections, monthly passes and recommended tickets.

(End of chapter)