That is all there is to it.
Being able to draw so conclusions now is already quite an achievent.
After the test experints concluded, so teams could return ho, but many mathematicians, physicists, and engineers stayed to continue working, so as representatives of their respective teams, others directly hired for long-term work at the experintal base.
Those who were hired were responsible for data work, monitoring tasks, computational-related assignnts, or joined the software support team to enhance the performance of the software.
And so on.
A major advantage of launching international projects of such a scale is the ability to retain top talents by offering many premier job positions, which in turn attract top talents to work on a long-term basis.
The next steps involved further analysis of the test data and preparation for the second experint.
Discussions for the second experint would begin a month later, transcending the testing phase to beco a formal, large-scale experintal endeavor.
To prepare for the first formal experint, there was much to do, such as upgrading and replacing equipnt and cataloging the area surrounding the experintal site.
Additionally, the detection devices placed within the experint would be more refined, and two more teams would be involved.
And so on.
Currently, the focus was on the research based on the test experint data because the results of data analysis were not definitive, and errors could erge during the analysis or even during the data collection phase.
All of the information would be made accessible to all major cooperating institutions, which could view the data on their computers and perform data collection and analysis.
Many scientists were eagerly waiting.
It was the first ti data from the material transmission experint had been made public, and within the data lay nurous pieces of information, so possibly undiscovered, with others containing extrely valuable content.
From these data, they could analyze and identify several things.
These data were like treasures.
Just as with particle collision experints, the Standard Model of particles was built step by step based on experintal data, and the discovery of new particles also stemd from data analysis.
As material transmission experints were a new field of study, there were undoubtedly many avenues of exploration to be pursued.
Their job was to use all ans to analyze the data to identify potentially researchable content and then to study it thoroughly.
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From the start of the experint to the completion of analysis, a total of three weeks elapsed.
Once the various teams had left, the workload beca sowhat lighter, and so mbers of the theoretical group also had more downti. However, rather than taking ti to rest, they were eager to begin another task—researching Space Link Technology in the hopes of constructing a more stable spatial channel.
It was a design task that necessitated a solid theoretical foundation to participate in.
Not just the four individuals from the theory group but also four from the Space Information Technology company team joined the design work.
This included two leading optical experts and two top researchers from the Quantum Physics laboratory of the Science Academy.
Zhao Yi was the core of the research team, and he had first established a basic frawork. Based on this frawork, the others worked on refining every detail.
It seed simple to hear, but those who took part knew the complexity involved.
A fully functional space connection structure required two hundred thirty-three points of beam production.
The number two hundred thirty-three was quite peculiar.
It was a pri number.
Having a pri number of beam production points ant that it was impossible to form a perfect closed loop, thereby preventing the channel from sustaining itself indefinitely.
For this reason, whether for space connections or energy transfers, it was impossible to construct a perfect channel, necessitating a continuous supply of energy to maintain the channel over long periods.
Even with an uninterrupted energy supply, the channel was imperfect, with one to six points of deficiency at any given mont.
What they were doing now was trying to perfect it as much as possible. However, perfection did not lie in addressing the missing points, but rather in building pathways for every point where beams occurred, aiming to capture as many points or Voidons as possible within a fixed spatial range.
During the design process, it was crucial not to increase the number of light points because doing so would also an expanding the coverage of space, which would not enhance stability but might actually destabilize the channel.
A more stable channel required increasing the energy at each beam production point without widening the beams.
This necessitated higher quality materials for the conduits.
The primary thod was to establish new branching paths; the connection of beam production points was not simply from one to the next. So points would link to one point while others connected to several or even dozens of points.
All these connexions were made based on theoretical foundations, and the more branching points connected, the more stable the channel beca.
Furthermore, all connexions had to be arranged within a disc, that is, a plane, aning the piping couldn’t intersect; otherwise, the connexion would fail to construct.
The above were the two main research directions, with others including polishing the light conduits and enhancing the smoothness of the conduits among the technical challenges.
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