Born Tech Mad

Nano-powder has 10,000 times the electrical conductivity of copper, high temperature resistance of 3700 degrees, and high elasticity. In addition to manufacturing nano-fibers, it is also the best electronic material.

To make a nanochip, you must create a nano integrated circuit board, and then use a laser to draw a circuit diagram on it.

This requires nanoplastics and nanometals.

The nanometer powder made by Ross is only 1 to 10 atoms in size. To mix nanometer powder with other substances, only atomic arrangement can be performed.

It is difficult for human beings to make nano plastics with super performance.

Because the advanced molecular pulverizer can only smash plastic to 1 micron, which is the level of 1000 nanometers, which is 1000 times that of atoms.

Such a large thing cannot be recombined with nanometer powder at the atomic level.

The stupidest way to make plastic into plastic atoms is to use them. The plastic is evaporated into a gas, and the gas contains countless various atoms. After finding those plastic atoms, they can be reassembled with nanometer powder to produce nanoplastics.

This process is as difficult as it is for others, but it is not so difficult for Rose.

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

Ross gave instructions to the Atomic Carbide Plant to suspend the production of 'atomic carburants', leaving all scientists waiting for their orders.

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

These gases are sucked into the pipeline, and through the low temperature treatment 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 floated to the 'atomic carbonization plant' through pipes.

After these gaseous atoms arrived at the atomic carbonization plant, Rose gave scientists orders to use the hadron collider to pop up the atoms and let them in the particle acceleration runway, speeding up the running, the required atom capture. Unwanted atoms are released.

Atomic Carbide Plant. 1,500 foreigners activated the Hadron Collider at Rose's order. Those inflowing gaseous atoms are driven by electric currents at speeds close to the speed of light. Rushing in the particle-accelerated runway.

Various kinds of atoms are driven by magnetic force from 100 compression chambers. Drilled into the Atomic Carbonation Laboratory.

Rose arrived at the Atomic Carbonation Laboratory and analyzed those atoms, the carbon atoms and hydrogen atoms contained in the plastic atoms. Combined with 12 other heteroatoms to form plastic atoms.

These different atoms are driven to the atomic carbonization chamber and placed in vacuum bottles. Just mix the various atoms needed to make plastic. Can form plastic atoms, add nano powder, can form nano plastic. If you add God particles, the performance is even better.

Rose spent a few days. Finally, the technology of recombining nanometer powder and plastic atoms has been solved.

100 kg of plastic evaporates into an atomic state, and impurities evaporate. The various plastic atoms formed weighed only about 100 grams.

Ross mixed 10 grams of nano-powder with 100 grams of plastic atoms. These atoms were arranged and recombined with each other to finally create a nano-plastic.

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

Rose painted this piece of nylon, a thin, transparent nanoplastic, and painted a plastic sheet.

They are one of the best materials for making nanochips.

With nanoplastics, nanometals must also be produced.

Rose used the same method to evaporate the metal into an atomic state, allowing the atoms to flow from the pipeline to the atomic carbonization plant, and then using the hadron collider to accelerate the separation of the atoms. Unwanted atoms were integrated into the air and returned to the universe. Driven into the atomic carbonization chamber.

Utilizing the replication and recombination capabilities of nano-powder, a small piece of nano-metal was recombined.

Because the metal contains too many atoms and is too complicated, 500 kg of metal can be vaporized into an atomic state, and only about 10 nanometer metals can be produced.

These 10 grams of nano-metals are valuable to Rose. They are 10,000 times more conductive, weigh only one-sixth of steel, and have 300 times the hardness of steel. It is surprisingly large, reaching 5 square meters.

Rose can't wait to return to the nanofactory with these two materials. Rose directly gives Britney and Tan Ying in the artificial intelligence building instructions to them to direct the robot production.

1,000 smart robots came in neatly. Under the direction of computer experts, they walked obediently to the production line. After networking with various laser high-precision machine tools and laser machine tools, they started the operation program and began to produce various nanometers. Components.

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 punch holes in these nanoplastics to facilitate the installation of various nanoparts.

Some robots operate laser and laser machines, drawing tiny circuit diagrams on top of nano metal.

Some robots, after mixing nano powder with ceramic powder, make poor nano ceramics, and use these nano ceramics as insulating materials.

Other robots operate laser machines to make nano-ceramics and nano-metals into nano-resistors and nano-capacitors that are invisible to the naked eye.

The manufacturing level of these parts cannot be completed by humans.

Because the nano-parts are too small for human eyes to see, only the powerful electronic eye of a robot microscope can see each part clearly.

After the robot's program is docked with the machine tool, the human-machine unit can complete tasks that cannot be completed by humans under the command of computer experts.

A nano-resistor process reaches 132 steps, and a nano-integrated circuit board requires 924 processes ~ www.NovelMTL.com ~ a complete nano-chip, and the various nano parts and nano-integrated circuits that need to be soldered reach thousands Each.

These techniques, each step wrong, will waste precious nanomaterials.

Robots are different. Each of their actions is of the highest standard, and each step is accurate to the nanometer level. They will not make mistakes because of exhaustion, they will not be distracted by inattention, and they will not be in a bad mood. Rather than want to work, they are the perfect technicians for humans.

In the nano-factory, a line of raw materials is being perfected over time. The production of nano-materials has also changed from the initial arc discharge method to the full use of 6 technologies to produce higher-quality nano-powder.

The ability of nano-powders to replicate and recombine allows them to easily recombine with a large number of atoms to form different nano-materials.

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

Everything will take time, and Rose can only wait. (To be continued.) Enable new URL