"I know," said Chen Zeshu, embarrassed, "I just couldn’t wait. Okay, when I go back, I’ll have—"
"Forget it. I’ll just go directly to the experintal group."
The nuclear fusion experintal setup required many materials that were not up to standard, but finding suitable materials on the international market was impossible because the demands were just too high.
Take the output end, for example.
Since the output end is not covered by a spatial do, it can be bombarded with neutrons. Neutron bombardnt in nuclear fusion is much stronger than ordinary radiation, so materials need to be highly resistant to radiation.
At the sa ti, the output end must withstand high temperatures and pressures. The nuclear fusion research group has demonstrated that the part in contact with the internal reaction needs to withstand temperatures of at least 3000 degrees Celsius.
Even using materials with a lting point of 3000 degrees Celsius and strong radiation resistance, it’s hard to say that they would be adequate because the materials need to be able to withstand harsh environnts over a long period without any interruption, ensuring no damage occurs in the process.
Therefore, materials are required to have a higher lting point and stronger radiation resistance, at least one grade stronger than the minimum requirent.
Such materials can be said to be nonexistent.
After the eting ended, Chen Zeshu attended two more small etings and decided to visit the experintal group as soon as he was free.
He started by having a direct conversation with the people in the experintal group.
Chen Zeshu wanted to find Zhao Yi, but Zhao was patiently conducting research. In desperation, he spoke with the technical staff in charge. Upon hearing Chen Zeshu’s various requirents, the technicians felt a headache coming on. They responded directly, "If you can apply for a special experint, your group can move the materials you normally use over here, then conduct a special experint. After compression, the physical properties of the materials will be greatly strengthened, which might et your requirents."
This response took Chen Zeshu by surprise. Not understanding the thod of creating materials through Z-wave experints, he readily agreed to put in an application and then went directly to the location of the Z-wave experintal group.
The experintal group was conducting frequent experints on compressing superconducting materials, with Zhao Yi leading the theoretical group to analyze the results and draw a series of conclusions.
After completing five experints, the experintal group encountered a problem. The large Z-wave Generator’s internal chanism suffered from issues that required parts to be replaced.
The technical group recognized the problem and reported on the fault. "Because Z-waves affect the generator, so parts have been compressed and shrunk, resulting in serious damage to the internal seal of the generator."
This problem had been anticipated before, but since experints were continuously being conducted, it hadn’t been given due consideration.
Now it needed to be taken seriously.
Zhao Yi decided to replace the temporary parts and conduct a major experint, "Even if it’s just once, we must use this experint to create the necessary compressed materials to protect the Z-wave Generator."
This approach was essentially an update of the materials used in the Z-wave Generator.
Once the relevant parts were updated, the Z-wave Generator’s capacity to endure the impact of Z-waves was greatly strengthened, and similar damage was unlikely to occur again.
There’s wisdom in the saying, "Sharpening your axe will not delay your job of chopping wood." Get the preparations right, and you can conduct related experints more frequently and with much greater precision.
anwhile.
The past five experints had already provided Zhao Yi with enough data to determine the rate at which particles could resist spatial compression.
Using the data from six experints, the theoretical group ca up with two possible outcos.
When superconducting materials were compressed by a factor of 2.9, their anti-gravity properties in a superconducting state were no longer detectable, but at a compression of 2.1 tis, faint superconducting state anti-gravity properties could still be detected.
Zhang Qican summarized the research findings, "So, one possibility is that the particle’s resistance to spatial absorption is exponentially reduced when compressed. Beyond about 2.2 tis, it’s no longer detectable."
"Additionally, there is also the possibility that between 2.1 and 2.9, there is a specific multiplier that could allow particles to completely resist spatial absorption."
These were two analytical outcos.
Zhao Yi, using the Causality Law in his thinking, reached a more precise conclusion. Indeed, there is a ’critical value’ for spatial absorption against compressed particles; when it is exceeded, the particle’s resistance to spatial pressure reaches equilibrium.
This equilibrium is like a shield capable of directly resisting slashes from blades. Due to the blades’ fixed sharpness, even if the shield is stronger, it remains unbreakable in place, achieving a balance with the cutting damage in practical terms.
Zhao Yi determined the critical value for particle compression to be more precise than the experintal data, with the range between 2.65 and 2.73.
This range of values imdiately reminds us of a particular—
natural constant, e, which is approximately 2.718.
Posing the question—
[Is the lowest multiplier (critical value) required for compressed particles to resist spatial absorption and reach equilibrium equal to the natural constant e?]
[A. Equal.]
[B. Not equal.]
[Law of Cause and Effect!]
[Answer: A.]
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