Born Tech Mad

The appearance of Dr. Zola and Hank made Rose feel the danger for the first time. to read

Although those two monsters haven't developed yet, they can still pose a threat to him.

Apart from improving his own strength, Ross has no other way.

In Yuta Company, in the nanofactory, thousands of engineers were busy all night, installing various machines and equipment according to the drawings provided by Ross to install the production line.

In the artificial intelligence building, the 3000-name robots have all realized intelligence, and these robots are enough to help Ross produce nanomaterials.

In the biological building, Tan Li led a group of biologists, no longer caring about any moral constraints, no longer caring about any objections from the world, breaking taboos, and various genetic experiments have begun.

Monkeys, orangutans, snakes, mice, and more than 100 kinds of creatures were used by biologists for biological experiments. Various genetic medicines were injected into the bodies of these animals, and screams of various creatures came from the biological building.

In order to deal with unknown enemies, we can only use genetic technology to unlock human potential.

In the weapon factory, Ross provided his own design of the 'Jerek Missile' to weapons experts and ammunition experts, and asked them to help him build this weapon system. As long as the system is manufactured first and the nanotechnology is displayed, it will be able to Direct manufacture of 'Jerek Missile'.

In the special steel factory, Ross ordered all production lines to be suspended, and all magnetic units were used to manufacture 25 times the special steel, which was used for defense.

At the arc reactor factory, Ross began to order experts to help him create a small arc reactor.

As long as the reaction furnace is manufactured, other parts can be miniaturized by nanotechnology in the future. Ross is making technical reserves for Iron Man's armor.

Ross can't sleep in Yuta Company. Except for himself, Yuta Company is all ordinary people. If one day he is gone, someone will come to Yuta Company to sabotage. Very serious consequences.

In response to a possible crisis, Ross placed a huge order to the National Laser Laboratory, requesting to purchase several high-power lasers, and modify these laser weapons. It can be turned into a high-power laser weapon, and coupled with an arc reactor, it can kill any creature with the power of a laser weapon.

In order to make Yuta Corporation impregnable, Ross didn't care about anything and planned to use chemicals. Toxic gas and chemical agent defenses have been added for each technical center of Yuta Company. Once an enemy enters Yuta Company and wants to steal any technology, they will be killed by poisonous gas and chemical substances if they are not careful.

In order to increase the security of Yuta Company, Ross put forward a new requirement for the artificial intelligence building. Each door of Yuta Company must add various fingerprints, pupil recognition technologies, and voice-activated recognition technologies, without the permission of Yuta Company. No one is allowed to enter the company.

Within ten kilometers around Yuta Company, 10,000 cameras must be added, not an inch of land can be spared.

The light source conversion factory must help Ross produce 2o large-scale light source scanners.

These 2o large-scale scanning instruments are equipped with infrared thermal energy scanning and biological wave detection functions. After they are connected with three supercomputers, they can scan any creature with a diameter of 1 mm within 10 kilometers around. Not even mosquitoes can escape the scan.

Even an ant wants to get close to Yuta Corporation. will also be monitored.

That night, Ross only slept for five hours. He never smoked, so he smoked a few cigarettes to relieve his worries.

early morning. The bright sun illuminated the sky, Rose got up early and ran to the nanofactory.

In the huge nanofactory with an area of ​​20,000 square meters, except for the ground floor, the other buildings are still rough, and Ross drilled into the ground floor. Check the installation of the production line.

Thousands of engineers and mechanics were busy all night, and the efficiency was quite high. One production line has been installed, and several other chemical pools have also been built, and the engineers and mechanics are still installing other production lines.

"We can start to make some carbon nanotubes first."

There was a little smile on the corner of Rose's mouth, and he ran towards the artificial intelligence building.

After Ross gave an order, 3000 robots with a weight of 300 kilograms lined up and followed Ross to the nanofactory like soldiers.

The robot walks at the same pace, and every time it goes down, there is a bang, bang, bang, and the ground shakes wherever it passes. It caused many employees to quickly avoid it. The scene was too spectacular.

Bringing a huge team of robots to the nanofactory, Ross began to give orders to the robots to start manufacturing the most important "carbon nanotubes" of nanomaterials in three ways.

The first method of producing carbon nanotubes was the 'arc discharge method', which is the most common method of producing carbon nanotubes.

Its production process: place the graphite electrode in a reaction vessel filled with helium or argon, excite an arc between the two electrodes, generate a high temperature of about 4000 degrees, evaporate the graphite, and produce fullerene (c6o ), amorphous carbon, single-walled or multi-walled carbon nanotubes.

By controlling the catalyst and the hydrogen content in the container, the production of carbon nanotubes can be adjusted.

This technology for manufacturing carbon nanotubes is relatively simple, but the generated carbon nanotubes are mixed with c6o and other products, so it is difficult to obtain carbon nanotubes with high purity, and all obtained are multi-walled carbon nanotubes. Single-walled carbon nanotubes are most desired.

100 robots began to work according to Rose's instructions. After they energized the graphite electrodes with the helium and argon furnaces, they sparked wildly. Graphite is evaporated directly, leaving behind a tiny layer of white substance.

These white substances are a mixture of fullerenes, amorphous carbon, and multilayer and single-layer carbon nanotubes.

Rose picked up a bit of the mixture to test. The results showed that the content of carbon nanotubes only reached 5%, and the other 95% were all fullerenes and other mixtures. Among the 5% of carbon nanotubes, 95% are multi-walled carbon nanotubes, and 5% are single-walled carbon nanotubes.

According to human research, the capacitance and energy density of single-walled carbon nanotubes are higher than those of multi-walled carbon nanotubes.

Multi-walled carbon nanotubes are easy to sink when the diameter reaches 6 nanometers, while single-walled nanotubes can reach hundreds of nanometers to tens of thousands of nanometers. The performance of a single wall is more valuable than multiple walls.

In order to solve the separation method of carbon nanotubes and fullerenes, Ross intends to use "grinding dispersion" and "sonic dispersion". Since other production lines have not been assembled, Ross can only order robots to mass-produce raw materials such as carbon nanotubes and mixtures. .

When other production lines are completed, the single-walled nanomaterials produced by robots will have better performance, and the purity will be more than five times higher than that of ordinary nanomaterials.

The performance of the manufactured nanomaterials is astonishing, not only the purity has been improved, but also the length-to-diameter ratio has reached 1oo:1, which is 10 times the length and diameter of ordinary carbon nanotubes.

The comprehensive performance of this carbon nanotube has exceeded the world's most advanced level by 20 times.

The production of carbon nanotubes consumes too much graphite. One ton of this material can produce only about 1 kilogram of single-walled carbon nanotubes.

Yuta Company is not short of money, no matter how expensive this material is, it has to be produced.

Although the production efficiency of robots is a bit low, if 100 robots work together, they can still produce a lot of carbon nanotubes in a day. As for the harmful gas produced by steaming graphite, it can be completely ignored for robots.

For this advanced material, Ross directed the machine to keep busy. (To be continued.)

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