Escape The Solar System With Millennium Technology

Chapter 226 – Nano Stealth Technology

After giving Christine to Yang Keer and familiarizing himself with the environment and experimental data, Wang Lei returned to the underground laboratory and began to work out the rescue of Christine’s daughter.

It is impossible to directly invade the U.S. network. Although the U.S. network disconnection plan cannot prevent Sunday’s invasion, Wang Lei does not want to get embarrassed because of this.

Some ways to find Christine’s daughter quickly are, for example, deploying a large number of nano-robots to the United States and monitoring the entire United States with surveillance satellites.

However, it takes time. One surveillance satellite cannot monitor the entire United States. At least four surveillance satellites are needed to monitor the entire United States, and the surveillance satellites must be stealth modified. In the previous war, Wang Lei found that the enemy seemed to be able to detect entering optical stealth. Equipment.

Wang Lei speculated that the enemy may have used the defects of optical stealth technology and could not visually interfere with multiple targets at the same time.

However, as long as the distance is long enough, optical stealth technology is still useful.

As for how to put nanorobots, Wang Lei’s idea is to directly install nanorobots into a meteorite, and then use the self-replication function of nanorobots to expand the number, and spread to the United States quickly like a virus through transportation.

A tube of nanorobot was extracted from the nano storage tank and transported to space, and then the nanorobot was poured on a meteorite ore with a diameter of one meter.

Then the nano-robot drilled into the meteorite iron and shot the meteorite iron towards the earth by the electromagnetic cannon. After counting, the meteorite iron will finally land in a suburb of Houston in the United States.

Because it is a meteorite iron, it will not be completely burned when it enters the atmosphere. After landing, the inner nano-robot will decompose the remaining meteorite iron as quickly as possible for self-replication.

These nano-robots will then look around for metal substances, or metal elements for self-replication.

When the number reaches a certain level, these nano-robots will be separated into two parts, one part stays in place, and the other part is randomly picked up by a vehicle to go to an unknown place. Calculated at this speed, no one will be produced. Months can cover the entire United States.

In order not to be discovered, these nano-robots will not decompose metal substances named in buildings and other names. At the beginning, they will decompose some cans or unimportant parts inside cars and similar things.(Read more @ wuxiax.com)

And as long as it encounters some places like metal mines, then nano-robots will enter the inside of the mines, start large-scale self-replication, and continuously output a steady stream of nano-robots to the outside world.

In order to be able to send pictures and other messages back, Wang Lei also asked the robot to steal the inventory of the phone lens manufacturer in a planned way.

The reason why you have to steal rather than make it yourself is that nano-robots cannot make special materials such as glass and photosensitive chips, and plastics, rubber, lubricants, and other items cannot be made as well.

After setting up the plan, Wang Lei began to think about how to upgrade the optical stealth technology. Over time, the effect of optical stealth will definitely get worse. Therefore, Wang Lei now urgently needs to find a material or technology that can perform optical stealth. , And it cannot have the same shortcomings as the existing optical stealth technology.

Wang Lei referred to many solutions, including those that directly absorb all light, some that bend the light, and some that scatter the light.

After many considerations, Wang Lei finally chose the method of letting light scatter. The other two methods have some fatal pain points, such as absorbing all the light, and a black hole appears directly in the space. This is not a shadow. What’s the difference between the body, it may attract the attention of the enemy even more.

And let the light turn, although this technology can be realized, but without mentioning its cost that can be scary, it is said that its abnormal level of manufacturing difficulty is completely impossible for mass production, and it is invisible to what it can. The object still has a certain size, and there is no way to make a big living person disappear completely.

But letting light scatter is different. Although it cannot be completely invisible, it is still difficult to find it in a complex or extremely single environment without careful observation, such as dense forests and Wanliwu. Cloudy sky, and in some special environments with obvious straight lines, you can also change the scattering angle to achieve a smooth transition.

In this way, the past will be the same no matter from any angle, and there will be no different or distorted pictures under multiple viewing angles.

This technology has two most important technologies, one is nanorobot technology, and the other is quantum computer.

It can change the light scattering at different angles and adjust it in real time. The best material available is nanorobots, and the shape of this nanorobot is different from the previous nanorobots. The surface is all smooth and right-angled. The circular sliding joint is much smaller.

The function has also changed from the previous joint to the support sliding function of the steel ball inside the bearing, so that there can be greater movement space and angle of movement between the support module and the support module.

The size of the sliding module has also been reduced from the original 30 nanometers to the current 5 nanometers. The reason why it has become so small is to allow the light to be scattered as much as possible.

The quantum computer is only responsible for counting the angles of light entering and exiting, and all other calculations are completed by a 1-nanometer superconducting chip.

The final etching of the chip, that is, the circuit with a width of only one nanometer, is all done by nano-robots, and the most special thing about this kind of chip manufacturing is that it must be etched in a weightless space.

The reason why it should be carried out in a weightless environment is that the one-nanometer line is actually a cylindrical pipe composed of carbon atoms. If it is done in a gravity environment, every carbon atom must be inserted correctly. It is heated so that the chemical bonds connect them, otherwise the carbon atoms will not stay in place all the time, and if the inlays are heated one by one, not only will it be extremely wasteful of energy, but also the time will be very slow.

And the manufacturing plant must be at the Lagrangian point to minimize the impact of the planet’s gravity and its cleanliness, at least 10,000 times cleaner than the earth’s air, otherwise the air will be scattered with fine particles. And dust will cause great damage to the chip.

To this end, there is also a separate design of air filtration equipment to continuously filter the environment in the factory.

There is still a lot of follow-up work to be completed in space, such as packaging and testing. It is always impossible for the chip to be shipped back to the earth for packaging and testing at the risk of damage.

Such a complicated design process takes a lot of time, at least two months, before the first batch of one-nanometer room temperature superconducting chips can be manufactured.

During this period of time, it is hard to develop and strive to double the general strength, especially the maritime power.