Born Tech Mad

The conductivity of nano powder is 10,000 times that of copper, the high temperature resistance reaches 3700 degrees, and the elasticity is super strong. In addition to making nanofibers, it is also the best electronic material. ⊥

To manufacture nanochips, it is necessary to produce nanometer integrated circuit boards, and then use lasers to draw circuit diagrams on them.

This requires nano-plastics and nano-metals.

The nanopowder produced by Ross is only 1 to 10 atoms in size. To mix the nanopowder with other substances, the only way is to arrange the atoms.

With the current methods of human beings, it is difficult to manufacture nanoplastics with super performance.

Because no matter how advanced the molecular pulverizer is, it can only pulverize plastics to 1 micron, which is the level of 1000 nanometers, which is 1000 times that of atoms.

Such a large thing cannot be recombined and docked with atomic-level nanopowder at all.

To make plastic into plastic atoms, only the most stupid way can be used. Evaporate plastic into gas, which contains countless various atoms, find those plastic atoms, capture them and recombine them with nano-powder to produce nano-plastics.

This craft is difficult for others, but for Ross, it is not difficult.

Because he has the most powerful hadron collider in the world.

Ross issued an order to the atomic carbonization factory to suspend the manufacture of the "atomic carbonization agent" and let all scientists wait for their own orders.

Ross asked the robot to turn on the production line, and tons of plastic evaporated into gas under high temperature.

These gases are sucked into the pipeline and processed at a low temperature of minus 100 degrees. The gas in the pipeline is affected by the low temperature, and many impurities and moisture solidify and fall down. Only some gas-like atoms drifted to the 'atomic carbonization factory' through the pipeline.

After these gaseous atoms arrived at the atomic carbonization plant, Ross gave the scientists an order to put these atoms into the Hadron Collider. Pop out the atoms, let them run at an accelerated speed in the particle acceleration track, the needed atoms are captured, and the unnecessary atoms are released.

In the atomic carbonizing agent factory, 1,500 foreigners followed Ross's orders. Launched the Hadron Collider. The influx of gaseous atoms, driven by the current, ran wildly in the particle acceleration track at a speed close to the speed of light.

Under the action of magnetic force, various atoms are drilled into the atomic carbonization laboratory from 100 compression chambers.

Ross arrived at the atomic carbonization laboratory to analyze and test those atoms. Plastic atoms contain carbon atoms, hydrogen atoms, and 12 other heteroatoms to form plastic atoms.

These different atoms are driven to the atomic carbonization chamber. Packed in vacuum bottles. As long as the various atoms needed to make plastics are mixed, plastic atoms can be formed, and nano-powders can be added to form nano-plastics. If God particles are added, the performance will be even better.

It took Ross a few days to finally figure out the technique of recombining nanopowder and plastic atoms.

100 kg of plastic, evaporated into atomic state. Impurities volatilize to form various plastic atoms. The weight is only about 100 grams.

Ross mixed 10 grams of nanopowder with 100 grams of plastic atoms. After these atoms were arranged and reorganized, a piece of nanoplastic was finally produced.

This piece of plastic is only 110 grams, but has an area of ​​one square meter, is as thin as paper, and has extremely strong performance.

Ross gives this piece of nylon as thin as it gets. After the pure transparent nano-plastic is painted, it becomes a plastic plate.

They are one of the best materials for making nanochips.

With nano-plastics, nano-metals must also be produced.

Ross used the same method to vaporize the metal into its atomic state, allowing the atoms to flow from the pipeline to the atomic carbonization plant. The hadron collider is then used to accelerate the separation of atoms, and the unnecessary atoms are merged into the air and returned to the universe, and the needed atoms are driven into the atomic carbonization chamber.

Using the replication and recombination ability of nanopowder, a small piece of nanometer metal was recombined.

Because metal contains too many atoms and is too complex, 500 kilograms of metal can be vaporized into an atomic state, and only about 10 nanometers of metal can be produced.

These 10 grams of nano-metals are invaluable to Ross. Their conductivity is 10,000 times stronger, their weight is only 1/60 of that of steel, and their hardness is 300 times that of steel. About 10 grams of nano-metals, the area Surprisingly large, reaching 5 square meters.

Ross couldn't wait to return to the nanofactory with these two materials. Ross directly gave instructions to Britney and Tan Ying in the artificial intelligence building to direct the production of robots.

1,000 intelligent robots walked in neatly, and under the command of computer experts, they obediently walked to the production line. After they were connected to various laser high-precision machine tools and laser machine tools, they started the operating program and began to produce various nanometers. Component.

Under the control of the program, some robots operate laser machine tools to cut nano-plastics and nano-metals into micron-sized blocks.

Some robots use lasers to drill holes in these nano-plastics to facilitate the installation of various nano-parts.

Some robots manipulate lasers and laser machines to draw tiny circuit patterns on nanometal.

Some robots, after mixing nanopowder and ceramic powder, made poor nanoceramics, and used these nanoceramics as insulating materials.

Other robots manipulate laser machines to manufacture various nano-resistors and nano-capacitors invisible to the naked eye from nano-ceramics and nano-metals.

The manufacturing level of these parts is beyond the reach of human beings.

Because the nano-components are too small for human eyes to see clearly, only the powerful electronic eyes like a robot microscope can see each component clearly.

After the program of the robot is docked with the machine tool, man-machine integration, under the command of computer experts, can complete tasks that humans cannot complete.

The process of a nano-resistor reaches 132 steps, the manufacture of a nano-integrated circuit board requires 924 processes, and a complete nano-chip has thousands of various nano-parts and nano-integrated circuits that need to be welded.

In these technologies, if every step goes wrong, precious nanomaterials will be wasted.

Robots are different. Every movement of them is of the highest standard, and every step is accurate to the nanometer level. They will not make mistakes due to fatigue, will not be distracted by inattention, and will not be in a bad mood. Instead of working, they are the most perfect technicians of mankind.

In the nanofactory, the production lines are being perfected over time. The production of nanomaterials has also changed from the initial arc discharge method to the full use of 6 technologies to produce higher quality nanopowder.

The replication and recombination ability of nanopowders allows them to easily recombine with a large number of atoms to form different nanomaterials.

All 3,000 robots were put into production, but they moved too slowly and the output was too low. The nano production line is too complicated. A complete product needs to go through hundreds to thousands of processes, and a product needs more than ten days from raw materials to successful manufacturing.

Everything will take time, Ross can only wait. (To be continued.)