Although the general plan has been determined, in the details, the collectors once again encountered a problem. The root of the problem also comes from the gravitational problem of the accelerated particle stream.

Gravity decreases with distance. In other words, the closer the distance, the stronger the gravitational force received. In the ring, the gravitational force received by the inner electric field generating part will be the strongest, which is like What matter does not rely on its rotation, but on its own strength can counteract the black hole.

　　 It is true that electromagnetic force has an effect on a small scale, but if it is used to counter the black hole-level strong gravitation...

"We need to design the orbital module to be strong enough, not only because the accelerated particle stream will bring highly reflective rays, but more importantly, it is used to counter the gravitational force of the particle stream. When this beam of particles around the star appears, it Gravity will gradually reach a level comparable to a black hole, so that stellar matter can be attracted."

"And the closest to the particle beam will undoubtedly be the strongest gravitation. Although on a large scale, the structure of the ring is not a problem, but on a small scale, it may be difficult for the orbital ring to rely solely on the strength of the structure to resist. Gravity at the level of a black hole is the force that can forcibly tear apart atomic nuclei."

　　 Collectors must consider this, otherwise, after the ring accelerates to a certain level, the ring will be torn apart in the vertical direction due to the strong gravitational force brought by the particle beam.

　　 "Then...then we let the orbital module rotate on its own long axis, so that it can resist gravity."

　　 Some individuals tried to put forward their own ideas, but this idea was quickly rejected by other kinsmen.

　　 "Nonsense! The ring is a whole, how to rotate?"

　　 "Yes, if the track is a straight line, it's okay to say, but this is a curved ring, which will inevitably cause the ring wall to bear tensile force when it is on the outside, and compressive force when it is on the inside."

　　 Collectors began to discuss this issue in depth. Not all individuals believed that the ring would be unbearable, and these collectors were confident about the longitudinal endurance of the ring.

　　 "There is electromagnetic force on a small scale, which allows the structure to deform."

"It depends on what the situation is. The gravitational force of a black hole is not at the level of the gravitational force of a planet. The distance between atoms and atoms will be shortened, and the volume of the orbital module will be reduced on a macro scale, which will inevitably lead to deformation of the entire ring structure. , Further leading to the failure of the electric field orbit to maintain the state of a circular ring, thereby causing the overall structure to collapse."

In order for all individuals to understand, the physical model of the ring is created again in the channel. This time the cross section of the ring is formed, and it is also the cross section of the orbital cabin. On this cross section, gravity will form forces in four directions. , Squeeze the cross section.

For the counterparts, the two forces are balanced. The forces in these four directions will not cause displacement of the cross section. Don’t forget that the premise of this force analysis is that the force-bearing object itself will not be destroyed by the force. The pressure in the direction will force the circular cross-section to compress, the nuclei will be squeezed together, and the electrons will be squeezed out. When the gravity reaches a certain level, it can even be squeezed into a neutron degenerate state.

　　 Therefore, the collectors are troubled.

　　 Finally, an individual put forward his own ideas.

　　 "It's all the same. We just need to think about the idea of ​​fighting against planetary pressure. We only need to use a very strong material to make the orbital module to counter the strong gravitational force of the particle beam."

　　 "What material?" the other collectors asked.

　　The proponent of the proposal explained his own way of solving this problem.

"Using a proton lattice, using this material, we can even omit the material for making strong electric fields. The proton lattice is a superconductor. The electrical properties of superconductors are different from ordinary substances. The conductor loses resistance, and the current flows through the superconductor. Without heat loss, the current can form a strong current in the wire without resistance, thereby generating a super strong magnetic field."

　　 "But superconductors have critical values, whether it is electric current, magnetic field or temperature."

"In the early stage of particle beam acceleration, it can be said that the subsequent particle beam is very close to the speed of light. Because of the strong inertia of the particle beam close to the speed of light, very high electric field values ​​are required to confine and deflect the particle beam. jobs."

Even a superconductor has its own limitations. If the current exceeds a threshold, the superconductor will lose its superconductivity and become an ordinary conductor. Not only the current, but also the magnetic field, temperature, etc., can make the superconductor lose its superconductivity. Inductance.

　　 Considering that the amount of current required by the ring is very large, and the field strength required for the deflection electric field is very high, collectors are not very optimistic about the application of superconductors in the design of the ring.

If you think about it carefully, you can understand that superconductors are different in nature from ordinary conductors. They have no resistance, and they have strong diamagnetism. After passing the critical current, the superconductor turns back to ordinary conductors, with resistance again, and diamagnetism is not the same as before. As good as that, the physical properties are directly changed into another look.

　　 In mathematical calculations, even if one hundred billion digits after the decimal point are changed, the result obtained cannot be the original one. Therefore, collectors who are pursuing foolproofness have not considered applying superconductors to the ring.

The proponent of the 　　 proposal rejected this view of the same clan ~lightnovelpub.net~ because it was very clear that their own clan's inadequate understanding of things led to misjudgment, and they did not consider some things.

"No, the superconductor can do the job, because the passing current will generate a magnetic field on the surface of the superconductor. When the current is large and the surface magnetic field exceeds the superconducting critical magnetic field, the superconductor will transform into a normal conductor. The fundamental reason lies in the structural state of the superconductor. It is broken, so it is restored to an ordinary conductor, but we have the gravitational force provided by the particle beam. This strong gravitational force will put a strong pressure on the proton lattice, forcing the crystal structure composed of hydrogen nuclei to not be broken by the strong electric field. The critical value of the superconductor can be raised, at least greater than the gravitational pressure on the hydrogen nucleus to break the state of the superconductor.

　　The problem was solved, and the collectors began to design more detailed parts of the orbital module. Just as the design of the orbital module was about to be completed, another individual shouted in the channel.

　　 "No! No! No need to make a proton lattice!"

　　 "What material is used without the proton lattice?"

　　 The other collectors were all stunned.

　　 "No, you got it wrong." The collector who raised the objection explained.

"I mean we can make liquid metal hydrogen first, and then use the gravity of the particle beam itself to finally compress the liquid metal hydrogen into a proton lattice. In this way, we can get a holistic proton lattice ring. Instead of relying on patchwork, you also know that patchwork has errors. It is difficult for us to be accurate to every particle, and as the number of patchwork increases, the error value will become larger and larger."