The research direction set by the theoretical team is to simulate the electromagnetic storm in the outer layer of the black hole to emit F rays on the periphery of the strong S-wave area.
But it is not known at all what the electromagnetic storm in the outer layer of a black hole is and what kind of specific reaction it will produce.
The content involved in this issue is very complex, and just theoretical research and discussion will not yield results.
There is no relevant research worldwide, and even the electromagnetic storm in the outer layer of a black hole is just a conceptual astronomical theory.
Astronomers all believe that an electromagnetic storm will be generated in the outer layer of a black hole, which will cause the black hole to spew out a large amount of material in stages and trigger large-scale astronomical phenomena. However, in fact, relevant research is only inference.
They relied on observed phenomena, relying on the study of cosmic rays, etc., and finally explained it by the explosion of a strong electromagnetic field in the outer layer of the black hole.
In other words, electromagnetic storms are just an explanation for astronomical phenomena, and it is naturally impossible to conduct related research.
Now we need to simulate the electromagnetic storm in the outer layer of the black hole. How to do it can only be studied experimentally.
The first thing to do is to carry out strong magnetic confinement and constrain the strong S-wave area to a closer distance, otherwise the experiment will not be able to proceed at all.
The current strong S-wave area is released 500 kilometers away. It is impossible for them to manufacture equipment that is 500 kilometers long. It is meaningless to just restrict the strong S-wave area. The strong S-wave area must be close enough to the manufacturing equipment. It is best
Just within a few dozen meters."
"We can create channels to connect the equipment and the manufactured field areas, so that complete constraints can be achieved."
"The new equipment has been manufactured."
"Magnetic field constraint equipment has also been shipped, which can create a super strong magnetic field of up to 10.3T!"
The performance of this magnetic field confinement device is amazing.
10.3T, the strength is very high.
Some research teams have released information about their results, claiming to have created ultra-strong magnetic fields with tens of T intensity. However, in fact, the magnetic fields they created have a very short duration, and they generally use pulse technology, hybrid magnet technology, or ultra-high magnetic fields.
Power electromagnet technology.
The magnetic fields created by these technologies are not stable.
If you want to create a magnetic field that covers a wide range and is continuously stable, you still have to use superconducting materials to create it in a conventional electromagnetic way.
The magnetic field equipment of the Strong S-Wave Research Group is the most advanced and high-end large-scale equipment in the country, capable of stably producing ultra-high-intensity and wide-area magnetic fields.
10.3T, the intensity is already very high. As long as it reaches 5T or above, it can be called a super strong magnetic field.
This device uses first-order superconducting materials that carry ultra-high current intensity.
The research team was very satisfied with the performance of the magnetic field equipment. After discussion, they set the magnetic field strength for the first experiment at 1T.
First, tests must be conducted to confirm that magnetic field confinement can shorten the release distance of strong S waves.
In fact, the magnetic field strength of 1T is also very high.
In comparison, some nuclear fusion technology research institutions manufacture tokamak annular vessels, and the magnetic field strength used to restrain ions is only about 1T.
After the magnetic field equipment was debugged, everyone in the laboratory was busy preparing for the first experiment.
The first experiment was just a test, hoping to confirm that this constraint is effective in shortening the release distance of strong S waves.
After this point is clarified, the magnetic field intensity will continue to be increased to allow the release of strong S waves closer.
Everyone is still looking forward to it.
Although they all have great trust in Wang Hao, after all, the so-called "shortening the release distance of strong S waves" is just a theoretical demonstration.
Soon it was time for testing.
Many people who have nothing to do with the experiment still just stay in the office because the strong S-wave release distance is too far and they can't see anything when they turn on the equipment. They just need to wait for the results.
Wang Hao also stayed in the office. He would not directly participate in similar experiments. He was mainly worried about safety issues.
Even if he wanted to get close to the experimental equipment, he would be dissuaded from leaving.
This is a very depressing place.
The experimental process is divided into two steps. The first step is to turn on the magnetic field equipment, and the second step is to turn on the strong S-wave equipment.
Wang Hao watched the test through a computer screen.
After turning on the equipment one after another, he waited patiently for the results.
Where exactly the strong S-wave area will appear still requires a military team to find it.
"It's going to take a while."
After Wang Hao made sure that the device was turned on, he simply went to the side to make a cup of coffee and said something to Huang Xing by the way.
At this time, I heard a call from the intercom, "Academician Wang, great discovery!"
"ah?"
Wang Hao was stunned when he heard this. He immediately picked up the walkie-talkie and heard Wang Qiang shouting from the opposite side, "It's right in front of you, less than a hundred meters away!"
He was startled and immediately ran over with Huang Xing, Helen and others.
Because the experimental goal is to shorten the release distance of strong S-waves, preferably to a range of tens of meters, the new equipment was installed and placed in the experimental room at the foot of the mountain.
Outside the experimental room is a large flat land covered with loess.
After the two devices were turned on, some people walked out of the experimental room. When they looked ahead, they felt something was wrong. Less than a hundred meters away, a large smoke suddenly appeared.
At first I thought it was a fire, but when I looked closer I was shocked.
They did not see a strong S-wave thin layer, but a lot of smoke came out of the ground, which was very similar to the scene when they first saw a strong S-wave thin layer.
Although they could not detect it, they determined that they had created a strong S-wave thin layer.
Wang Hao and people from the theoretical team also came to the scene. They saw the smoke filling the air from a distance and quickly asked Wang Qiang to command to shut down the equipment.
Confirmation is no longer needed at this time.
Wang Hao saw the smoke-filled scene with his own eyes, and naturally determined the existence of a strong S-wave thin layer.
He immediately asked someone to notify the military team, so there was no need to continue searching.
The military sent several helicopters along the manufacturing direction to search for strong S-wave thin layers. The nearest helicopter was 50 kilometers away and had no idea what was happening at the experimental base.
This chapter is not finished yet, please click on the next page to continue reading the exciting content! An hour later, the military team arrived at the scene, and many people started excavation work with tools.
the other side.
Wang Hao and others were discussing the experimental results. They had no idea that the strong S-wave area produced in the first test was so close.
Zhou Zhiwei said with surprise, "The effect of magnetic field confinement is amazing!"
"Sure enough, as Academician Wang analyzed, magnetic confinement has a direct effect on strong S waves!"
"The 1T magnetic field restrains the strong S wave from a distance of 500 kilometers to 81 meters..."
Others felt equally incredible.
They all believed in the research results of the theoretical team, but they did not expect the results to be so good.
The magnetic field equipment used by the research team can create a super strong magnetic field of more than 10T, but the result is only one-tenth of the intensity...
It seems that the goal has been achieved?
A group of people looked at Wang Hao.
Wang Hao took a deep breath and said, "This shows that our judgment is biased."
"The role of the magnetic field is not just a constraint, but a direct restriction. It can even be understood as directly reducing the intensity of the S wave."
Strong S wave has two properties.
One attribute is the annihilation field strength, and the annihilation field strength is fixed.
Although it is impossible to make an accurate measurement, based on the subsequent analysis of a large number of materials passing through the field force, the annihilation force field strength is probably between 5.0 and 5.5.
Another attribute is the intensity of the S wave. Just like gravitational field technology, the S wave intensity of a strong S wave can be understood as ‘gravitational strength’.
The intensity of the S wave is high, which is manifested in the internal spatial impact on matter, or simply understood as 'gravity'.
Now the effect of creating a magnetic field on strong S waves is to reduce the intensity of the S waves.
"That's not just restraint, it's a direct reduction in intensity."
"Perhaps, when the magnetic field intensity reaches a certain value, the S-wave intensity returns to zero, and the strong S-wave will turn into a strong annihilation force field..."
This is Wang Hao's speculation.
To be continued...