Free Web NovelChapter 1239: Chapter 597: What is This? Super High-Temperature Superconducting Materials?_2
Significant discoveries like this definitely call for an interview.
In the past two years, Zhao Yi had rarely accepted interviews, but this time he made a public appearance in front of camera lenses and seriously discussed the issue of particle degeneration in an anti-gravity environment.
First, Zhao Yi explained particle degeneration, confirming it was a very significant discovery that could even overturn physics, and might potentially shake the status of Einstein’s Theory of Relativity.
Afterward, Zhao Yi began to discuss the technical issues, "We are trying to study nuclear fusion reactions in an anti-gravity environment."
"Nuclear fusion represents the future of energy, and the discovery of particle degeneration in an anti-gravity environment has made controlled nuclear fusion possible."
"We have already achieved some results, but we are still far from completion," he said.
The journalist asked, "Can you talk about some of the related technology?"
"Of course," he said.
Zhao Yi answered, "We are combining anti-energy barrier technology with nuclear fusion. By making the anti-energy barrier serve as the isolation layer for nuclear fusion reactions, we could theoretically achieve perfect control over nuclear fusion."
"But—" he said, shaking his head, "the anti-energy barrier is a new technology that we have not completely understood yet; these ideas remain theoretical for now and we will gradually move on to experimentation in the future."
"Although we have encountered many problems in development, we believe that one day we will succeed. If not in one year, then in two; if not in two years, then in ten. One day in the future—"
Zhao Yi spoke with unwavering determination, essentially conveying that controlled nuclear fusion is the future, and that we must steadfastly continue our research for generations, be it two, three, or even five generations.
A single stone stirred up a thousand waves!
When the interview video was broadcast, it immediately garnered worldwide attention.
Various research institutions indeed abandoned the ’magnetic confinement + anti-gravity technology’ approach, instead focusing on the ’anti-gravity technology + anti-energy barrier’ combination.
Because it sounded very reliable.
Based on the information released so far, the anti-energy barrier could indeed directly block energy; so what was the need for magnetic confinement?
The anti-energy barrier was obviously the best choice!
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Many institutions began to pay attention to the research on the anti-energy barrier, and quite a few hoped to obtain technical details related to the development of the anti-energy barrier from domestic anti-gravity experimental groups or the Institute of Mechanics. ƒreewebɳovel.com
Of course.
Even the Institute of Mechanics, which had just discovered the anti-energy barrier, could not simply share the technology with the whole world. What they could obtain were only two pieces of information: "increase the power" and "rearrange the beam combination."
These two pieces of information were still of great value, but any institution would definitely need to conduct many experiments before they could truly create an anti-energy barrier.
As for control—
Zhao Yi estimated that without twenty or thirty years, it was not even worth considering.
To speak of controlling the anti-energy barrier when they could not even maintain the barrier for a longer period of time was foolhardy, and to maintain it permanently was simply impossible within ten years.
Time is money.
Zhao Yi’s public disclosure of particle degeneration and control of fusion by the anti-energy barrier was indeed done for a reason.
It could be understood as ’routine publication of research results.’
Domestically, with the introduction of anti-gravity technology, continuous research had always been conducted at a faster pace than other institutions.
Many institutions would want to know the state of domestic anti-gravity research, so the findings were published periodically.
When other institutions learned that the domestic anti-gravity research team was conducting research on controlled nuclear fusion and intended to sustain this research over several generations, they would inevitably be reassured.
Because it was a very long-term project.
These institutions did not doubt the information received; ’particle degeneration’ was already a significant discovery, and they naturally understood that controlled nuclear fusion could not be completed in a short time and would rightfully require a lengthy period.
Simultaneously, they also immediately embarked on similar research.
This path was clear.
Controlled nuclear fusion was too important. Since the concept of controlled nuclear fusion was proposed, it had attracted countless institutions to participate in research, and most scientists believed that controlled nuclear fusion represented the future of energy, which is the foundation for development and survival. freeweɓnovēl.coɱ
Therefore, many well-known institutions received substantial external funding to begin research on the ’anti-energy barrier’ and ’nuclear fusion in an anti-gravity environment.’
This was also one of the purposes for releasing the information.
Research into anti-gravity nuclear fusion required large investments and experimental scale, so complete secrecy was impossible, and it was better to be public about it, letting everyone know what they were researching. As for how far the research had progressed?
Sorry!
That’s a secret!
Afterward, Zhao Yi was no longer involved. He only returned to the capital to attend a ’spacecraft’ meeting and accepted an interview from the media. He did not even stay at home for two days before he hurried back to the experimental base.
The second experiment was about to begin.
The wrap-up of the last experiment was almost done, and the experimental materials underwent various checks, including very detailed checks.
All other data was within expectations, but one piece of data deserved attention: the conductivity of compressed metals had increased.
This was a very useful discovery.
For metal conductors of the same material, mass, and length, only differing in thickness, the conductivity of the compressed metals showed a significant enhancement, indicating that the electrons in the compressed metals had become significantly more active.
