However, it seems unnecessary.

Yixing launched a high-power Z-wave satellite, which directly established a space channel from the earth to Mars, allowing ordinary anti-gravity spacecraft to shuttle directly to Mars.

This is just the beginning.

Zhou Hong, the general manager of the spacecraft project team, said with certainty in an internal meeting, "Yixing will definitely continue to build a space channel, and the next time it may go directly to Pluto, Mercury, or even Europa, they will respond to The stars in the solar system have undergone a series of explorations."

"Google is very meaningful because of the environment on Goliath, maybe there is water."

"Mercury will become a transit station to the sun. Yixing constantly launches energy-concentrating satellites, and always needs a transit station for regulation. Maybe Mercury will become their base."

"Pluto will become their outpost for exploring the outer solar system!"

Zhou Hong’s analysis made the participants nod frequently. They are all members of the project team and national strategic talents. At the same time, they are also very much looking forward to the completion of the spacecraft project, so that the spacecraft can flex its muscles and truly explore the universe in the future.

However, what makes them depressed is that there is no end in sight for the completion of the spacecraft, and the exploration of the solar system is almost complete.

So what's the point of a spaceship?

Of course.

Spacecraft can achieve exploration outside the solar system, but at the same time it will greatly increase the difficulty of their projects.

The current situation is that after the spacecraft is manufactured, if it cannot get out of the solar system, it will become a big chicken rib.

So the spaceship must go out of the solar system when it is pushed, but how difficult is it to get out of the solar system?This is completely different from the exploration of the solar system. What kind of technology is needed must be constantly demonstrated and thought about.

The exploration in the solar system, at least what kind of stars exist, is well known.

It's different outside the solar system. It's very scary just talking about the distance.

Outside the eight planets of the solar system is the Kuiper belt, which is outside Pluto and is the birthplace of short-period comets. In recent years, the Kuiper belt has only come into the sight of astronomers. There are a lot of asteroids concentrated in the area. Among them, Pluto is A typical Kuiper belt star, at the edge of the Kuiper belt.

Based on the Kuiper belt, the radius of the solar system is as high as 100 AU (about 150 billion kilometers).

The outer side of the Kuiper belt is the Oort cloud. The Oort cloud is only predicted to exist, but the possibility of existence is very high.

The Oort cloud is the birthplace of long-period comets. It is a spherical cloud surrounding the solar system, full of many inactive comets, about [-] to [-] astronomical units from the sun, and the largest radius is close to one light-year. .

Astronomers believe that the Oort cloud is the remnant of the nebula that formed the sun and its planets 50 billion years ago and surrounds the solar system.

The radius of the Oort cloud is close to a quarter of that of Proxima Centauri.

If you are exploring outside the solar system, you must at least head towards the Proxima Centauri galaxy. The nearest star to the solar system is the third star of the Alpha Centauri star system, and the distance from the sun is about [-] light years.

Alpha Centauri is also very close to the sun, only a tenth of a light-year away from Proxima Centauri.It is another star of Alpha Centauri, and it also has a rather peculiar red circle.

Whether it is Proxima Centauri or Alpha Centauri, the distance from the solar system is calculated in light-years. Even if you have space shuttle technology, it is very important to know what will happen, what you will see, or what problems you will encounter when traveling such a long distance. It is difficult to directly predict, and the spacecraft project team must study related technologies in advance during the process of manufacturing the spacecraft.

This is the biggest difficulty.

When the spacecraft's exploration mission is enlarged to explore outside the solar system, the project team feels that the spacecraft manufacturing work is even more difficult to complete.

Fortunately, the project team is not without results.

The biggest achievement of the project team comes from the nuclear fusion research and development team. They overcame many difficulties and successfully manufactured the second nuclear fusion device.

This nuclear fusion device only needs to replace the fuel once every two years, and the output unit can provide a stable power of 430 million kWh.

The power of 430 million kWh is already quite high.

A single large unit in a general power plant has a power of only one million kilowatts. For nuclear power units, the output power of the first nuclear power plant in China is only 310 million kwh.

430 million kWh is a very impressive data, enough to support the spacecraft, turn on the high-power Z-wave, and quickly complete the space shuttle.

Of course.

The manufacture of the second nuclear fusion device also costs a lot of money, directly costing as much as 690 billion yuan, which is more valuable than a large aircraft carrier.

In addition, after the device is manufactured, it is a circle wider than imagined. It is used to manufacture a spaceship, which will also make the outer layer of the spaceship an extra circle, and other positions need to be enlarged accordingly.

These are questions.

Fortunately, the problem of project funding is not a problem, because the spacecraft project has more than a dozen major countries participating, and the country is responsible for the overall design and supervision, and the funds invested are only spent on a few core components.

The nuclear fusion device, also known as the power plant, is one of them.

This part of the cost is invested domestically, and the huge capital investment comes from direct appropriation of project funds, and most of the funds come from high-tech income.

For example, anti-gravity technology.

The sale of anti-gravity technology and devices has brought in a lot of income.

In addition, spatial information technology companies also have continuous large profits.

Putting the two together can support the spacecraft project team, carry out the research and development of core components, and continue to support the project.

At this time, Zhou Hong was sitting in the office, reviewing the submitted documents.

The spacecraft project is too large, and there are at least hundreds of R&D and manufacturing documents that need to be processed every day.

For ordinary applications and reports, Zhou Hong will hand them over to the team leader of the relevant team, but he must be responsible for some of them.

For example, the project research and development application in hand.

"Academician Zhao's application?"

Because the application was made by Zhao Yi, it was directly handed over to Zhou Hong, and he even wanted to approve it directly. What is there to see about Academician Zhao's application?Definitely agree first.

When he saw the funding applied for, Zhou Hong still hesitated. The initial funding was 20 billion, which was too huge.

He looked carefully.

The title of the project is a bit unremarkable, "Z-wave detection technology? Does detection technology require so much money for research and development? 20 billion is enough to manufacture several large Z-wave generators."

Zhou Hong continued to read to know what the Z-wave detection technology is.

"Instantaneous detection of Z-wave coverage, is there a large-mass obstacle?"

"This is timely rain!"

The spacecraft project team has been worrying about how to avoid the danger of ultra-long-distance exploration and space shuttle.

Theoretically speaking, there may be accidents in the space shuttle with the unit of light-years. It is not an accident that directly installs a super-large star, but is worried about encountering a small star, such as dozens of tons or hundreds of tons. The small stars are the most dangerous.

On the Z-wave coverage route, there are supermassive stars, which will directly affect the Z-wave compression ratio, making it impossible for the spacecraft to complete long-distance shuttles.

For example, the planets in the solar system.

If the Z wave directly hits Mars, the Earth, etc., there will be no ultra-high-magnification compression at all, and the space shuttle will not succeed at all, and the danger will be avoided directly.

Asteroids are different, because the mass is limited, and it will also greatly affect the compression ratio, but it is not to the extent that the shuttle fails. Instead, it will allow the spacecraft to shuttle to a certain extent, and the shuttle distance is not as far as expected. On the way, there is a certain probability that it will directly hit the asteroid.

The "Z-Wave Detection Technology" applied by Zhao Yi now aims to detect whether there is an asteroid blocking the shuttle route.

"approved!"

"Pass directly!"

"If this technology can be developed, the big problems of the project will be solved!"

Zhou Hong thought so, but he had no way to do it himself. He held a symbolic meeting for the approval of the initial 20 billion project, and video-linked Zhao Yi to let Zhao Yi explain the relevant research and development.

Zhao Yi gave a brief explanation, explaining the necessity of Z-wave exploration technology and its importance in the realization of space exploration. The project team gave an approval and the application went to the senior leaders.

The senior leaders didn't hesitate at all, and even asked about the content before directly approving it.

-

Zhao Yi applied for the initial funding of 20 billion yuan, most of which will still be used to build laboratories and manufacture sophisticated Z-wave generators.

A newly established laboratory requires a lot of precision instruments, and some even need to be customized and manufactured, which will definitely cost a lot of money.

In addition, research also needs auxiliary personnel, and experts in the fields of microphysics, optics, electronics, etc. are indispensable.

After Zhao Yi applied for the project, the Optical Laboratory of the Academy of Sciences, the Department of Physics, the Institute of High Energy and other departments directly dispatched the required personnel. There are three with the title of academician, and there are four other researchers and one associate researcher.

Zhao Yi also recruited someone from the theoretical group as an assistant to be responsible for some calculation work.

He quickly ordered a high-precision small Z-wave generator, and more than a dozen high-precision electronic detection devices.

In addition, equipment for establishing a vacuum environment is also essential.

After completing a series of orders, many people came to the laboratory, and Zhao Yi called everyone for a meeting.

This is an early meeting.

"Although most of the equipment has not yet arrived, our research has already begun."

Zhao Yi said, "The first thing to do in this research is to analyze whether various confineable particle beams can quickly test the behavior changes of particle beams through experimental means."

"What we have to do now is theoretical research, come up with some feasible solutions, and lay the foundation for real research!"

What the research has done is devise a scheme to detect changes in the behavior of the particle beam.

Of course, first of all, it is necessary to design various particle beam generation schemes and restrict the particle beams to a certain extent.

Among them, the most intuitive and feasible solution is to confine the charged particle beam.

The charged particle beam can be restrained only by using a magnetic field. After it is launched, it will continue to circle under the action of the magnetic field and can be controlled and detected.

But charged particle beams are only one option.

In fact, Zhao Yi does not have much hope for the detection scheme of charged particle beams, because the detection of the behavior of charged particle beams will be seriously affected by current and magnetic field.

That is, the confinement of a charged particle beam is easy, and the detection is too difficult.

He hopes to study whether the energy beam will be affected by the space compression environment.

For example, the most basic beam.

Theoretically speaking, energy is not affected by space compression, but the theory he studied may not be completely correct.

In addition, it is not necessarily true to say that the beam is pure energy and is completely unaffected.

For example, the most direct counterexample is that the light beam will be affected by the super-large gravitational force to produce the gravitational waves that can be observed.

The appearance of gravitational waves is directly related to space-time.

Space-time is time and space.

The bending of the light beam will be affected by time and space, and the compression of space is not necessarily, it only acts on space, and may also affect time.

In the field of time, he did not conduct in-depth research.

Now it is time to study and think about it in depth.

Chapter 652 Zhao Yi: "Space and Cosmology"

On the issue of 'whether the space squeeze will affect the energy beam', what can be done for the time being is only in-depth thinking.

Even if it is to study the impact of space squeeze on particle beams, to carry out a series of experimental design preparations, and to wait for various high-precision instruments to be equipped, it is uncertain what conclusions can be drawn and how deep the research can be carried out. The research difficulty of energy beams is not of the same order of magnitude as that of particle beams, because energy beams are affected by space squeeze, and the impact is very small, so small that it is impossible to detect them in normal experiments. In addition, if you want to control energy beams in a small range, Almost impossible to do.

The underlying logic of anti-gravity technology is to design the beam to rotate continuously, but in fact, that is not a real rotation, but a process of continuous annihilation and regeneration of the beam, which is tantamount to forcible physical intervention to make the beam route rotate.

In short, it is temporarily impossible to study energy beams experimentally.

"That may not be done through experiments at all, but requires close observation of black holes."

In the theory studied by Zhao Yi, it is believed that black holes are aggregates of high-intensity compressed particles, and the black holes themselves continuously release Z-waves.

If the light beam is to be affected by the squeeze of space, it must manifest itself next to the black hole.

This observation can only be expected for the time being.

In the current experimental preparations, it is more practical to study particle beams with mass.

This research is also very important.

The research on Z-wave detection technology will directly affect the safety of space shuttle, and can directly determine the distance of space shuttle.

Safety is more important than distance.

Technology is gradually improved step by step, and it is impossible to reach the key point in one breath.

Zhao Yi hopes that the detection of the properties of the particle beam can first reach the level of determining the space compression ratio of "ten to the eighth power", so as to ensure that the space shuttle distance can exceed dozens of astronomical units, that is, shuttle from the earth in one breath to the Kuiper Belt.

This shuttle distance is not too fast, but it is enough to support the spacecraft and slowly fly out of the solar system.

-

The research on Z-wave detection technology is still in progress.

The third-floor laboratory on the side of the university also has a signboard of "high-precision testing laboratory". Even the leadership of Zhengyang University doesn't know what kind of "testing" it is, but they don't know. hinder their joy at the establishment of the laboratory.

New research is carried out in universities, and the benefits to universities are too many.

First of all, there are many top professors and experts who come to work in the laboratory, some of which are even out of reach of universities.

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