The top student must be diligent

Coupled with the one-to-one corresponding experimental data, he can activate his "material mastery" and perform plug-in level analysis on these materials.

"Well... this is TBCCO, thallium barium calcium copper oxide. The superconducting critical temperature is as high as over 100K, which is dozens of degrees higher than yttrium barium copper oxide."

"According to the experimental results... this is specifically TBCCO-2212. The superconducting critical temperature is 110K, the superconducting gap Δ≈20-30meV, and the lattice parameters are a≈3.85, b≈3.85, c≈30.6."

"The phonon mode associated with the copper-oxygen plane can be easily observed in the Raman spectrum with a frequency of ≈31."

"Under the observation of ARPES, it shows a multi-band structure, and the Fermi surface is composed of multiple electron and hole pockets..."

Xiao Yi groped his chin.

Then, with a slight movement in his heart, [Material Mastery] began to activate invisibly.

In an instant, the world in his eyes changed.

The TBCCO-2212 sample in front of him seemed to be infinitely magnified, and finally all the details inside appeared before his eyes, almost every detail - probably, every detail was not enough to describe this level of detail.

It can only be said that his eyes seemed to have turned into a microscope, able to directly observe the microscopic level of the sample in front of him.

Of course, the level of detail he can observe is ultimately limited by the level of detail in those experimental data.

The level of detail of these experimental data is limited by the resolution of the experimental instrument.

At the same time, the overall wooden barrel principle is followed, and the final level of detail is completely determined by the experimental instrument with the lowest resolution.

This is why the experimental instruments Xiao Yi ordered for the Science Island Laboratory are almost all top-notch in terms of resolution, just to maximize his [Material Mastery] ability.

As for the experimental data he has now, in terms of effectiveness, it is much worse.

There is no way around this. After all, apart from him, probably no laboratory in the world has such high requirements for the resolution of experimental equipment. Basically, there will be equipment with lower resolution.

For example, Sun Lina's laboratory has equipment with very average resolution.

He shook his head, forget it, just use it reluctantly. After all, he couldn't go to Sun Lina and tell her to replace all the equipment with poor resolution.

No longer entangled, he then carefully analyzed the sample in his mind.

Compare the microscopic information obtained through [Material Mastery] with the XSC theory, and then according to the guidance of the XSC theory, he can use the simulation derivation function attached to [Material Mastery] to simulate changing the structure of the superconducting interface to observe whether can change the superconducting properties of this material.

Whether it is high-temperature superconducting or low-temperature superconducting, there are three properties, namely critical temperature, critical magnetic field strength, and critical current density. If the conditions of the material are within these states, it will enter the superconducting state, but if it exceeds These criticalities will then be quenched.

So temperature is not the only important condition, but so are the other two.

Beyond that, it’s the basic properties of the material, especially its workability.

Only the better the processability is, the more suitable it is for large-scale use, because this involves processing costs. The easier the material is to be processed by cutting, stamping and other processing methods, the easier it is to create the form needed by humans.

For example, the two superconductors, yttrium barium copper oxide and niobium titanium alloy, are better in terms of critical magnetic field strength and critical current density than yttrium barium copper oxide and niobium titanium alloy.

However, it is precisely because yttrium barium copper oxide is a ceramic material with high brittleness and its processability is far worse than that of niobium titanium alloy. In addition, its synthesis cost is high, so it has not been used on a large scale.

Xiao Yi's goal is to design a high-temperature superconductor that is good enough in terms of processability and low enough in synthesis cost.

In this way, he began to try continuously. At the same time, it was not just the TBCCO in front of him, but also various other materials, such as BSCCO, YBCO, FeSe, etc.

Time also passed quickly.

It took almost an hour to analyze all the samples in front of me.

As the effect of [Material Mastery] ended, the picture in front of Xiao Yi gradually became longer, until finally, the microscopic world in his field of vision returned to the macroscopic world.

"Hmm...the resolution of these data is still not good enough."

Shaking his head slightly, Xiao Yi felt a little pity.

Although today's analysis is not without success, it is still limited by the resolution, so the gains are not very great.

Maybe you can go to other more high-end laboratories, such as the Condensed Matter Physics Research Center in Shangjing. The experimental instruments there are still high-end enough.

But the problem is, it's more curled over there than here.

Reservations are required to use the laboratory, not to mention that he has to conduct a large number of experiments. It is even more troublesome to prepare a large number of high-temperature superconductor samples and then conduct large-scale measurements.

"After all, it's not your own laboratory."

Thinking of this, Xiao Yi is even more looking forward to the completion of the Science Island Laboratory.

Although the Science Island Laboratory will not be as big as the Condensed Matter Physics Research Center, the experimental equipment is guaranteed to be first-class.

"but……"

Xiao Yi suddenly recalled some of the feelings he had just had during the analysis process through [Material Mastery].

At this time, an idea popped up in his mind: "Perhaps, I can write a textbook on experimental data analysis based on the feelings that [Material Mastery] brought me?"

Although others cannot have the ability of [Material Mastery] like him, he can summarize a set of experimental data analysis methods suitable for everyone to learn based on the role brought by [Material Mastery].

This method definitely goes beyond the scope of all current experimental data analysis methods and can greatly improve the scientific research efficiency of scientists in related fields, especially in the field of materials.

With this idea in mind, Xiao Yi was somewhat tempted.

Producing papers or important research results is one aspect of scientific research, and writing textbooks is also one aspect of scientific research.

The former is to explore scientific research, while the latter is to lay the foundation for scientific research.

The two cannot be compared, but it is undeniable that without the latter, there would be no former, and without the former, there would be no more profound latter.

It is a question of which came first, the chicken or the egg.

A classic textbook can guide more people to make more achievements.

"Well... that's it. Let's use the time we wait for the Science Island Laboratory to be built to write such a book! The matter of synthesizing high-temperature superconducting materials will be discussed after the laboratory is built."

Xiao Yi made a decision quickly.

As for the name of this book, let's call it "Principles of Experimental Analysis".

The macroscopic method he summarized from the microscopic can be called "principle" anyway!

In addition, while writing this book, a large amount of experimental data is also required, which can also help him design high-temperature superconducting materials, or at least accumulate a large number of experiments.

Just as he began to think about how to structure this textbook, the door of the laboratory was suddenly knocked.

Xu Ming and others went to open the door, and then saw Pan Wei and other big guys from the Quantum Information Department coming over.

The eyes of the little Karamis suddenly widened.

"Academician Pan! Academician Chen! And..."

Generally speaking, even if they are in the same school, most of the students in a college can't even recognize all the teachers in their own college, let alone teachers in other colleges.

But there was no way. Academician Pan Wei was too famous in HKUST, so even students from the Department of Materials could recognize this leader in the field of quantum information at first sight.

Pan Wei smiled and nodded at them, then looked at Xiao Yi inside, and then said to Xu Ming and others: "We are here to find Xiao Yi. Please help call him."

"Okay...Okay!" Xu Ming and others nodded, and finally ran to Xiao Yi's side and greeted Xiao Yi.

Xiao Yi turned around and was stunned when he saw Pan Wei and others.

He had naturally met Pan Wei and others, or when he had a meeting, but he hadn't seen them much since then.

He also learned from President Bao that the resistance in the construction of the Science Island Laboratory came from these people.

He just didn't know why they came to him now.

Then he walked over and said, "Academician Pan, Academician Chen, why did you come here to see me?"

Academician Pan smiled and said, "First of all, I want to congratulate Professor Xiao for studying the high-temperature superconductivity mechanism. Maybe he will win the Nobel Prize in the next few years."

Xiao Yi smiled and waved his hands, saying, "Nothing, it's all luck, luck."

Academician Pan laughed, "How can this be called luck? This is all strength."

Looking at the other party's appearance, Xiao Yi raised his eyebrows. It seems that this is considered to be making friends with him?

He smiled and said, "Academician Pan, you should tell me what you are here for. If you want to discuss the high-temperature superconductivity mechanism with me, I am very welcome."

Academician Pan was stunned, and looked at Academician Chen and others, then smiled and nodded, saying, "It is true. Professor Xiao should also know that quantum computers, especially superconducting quantum computers, also need some research on superconductivity mechanisms, so we really want to invite Professor Xiao to hold such a lecture on XSC theory. At that time, our Quantum Information Research Department will also organize everyone to exchange and learn."

"Our Quantum Information Science Laboratory will also organize it." Academician Chen next to him also smiled and nodded.

Hearing what they said, Xiao Yi understood that they really wanted to build a good relationship with him.

Although he was not very interested in these things outside of scientific research, he certainly would not refuse the other party's invitation to him to give a lecture on XSC theory.

As for making friends, let it go.

In the scientific community, strength is supreme after all. A person who relies on bragging but has no actual achievements will only be ridiculed, while a person who truly has achievements and never brags can be respected.

"Of course, no problem." He nodded.

Academician Pan laughed, "That's good."

"In addition, Professor Xiao, I also want to ask, are you interested in quantum information?"

Academician Pan said: "Now the academic community says that as long as it is a problem that Xiao Yi is interested in, it will definitely be solved, so if you can join us, maybe we can make further progress in quantum information?"

"Quantum information?" Xiao Yi shook his head and said: "I really don't have much interest. In this field, we have Academician Pan and you can support it in our country."

Current quantum computers can only calculate one algorithm, and they are completely unable to achieve general computing like classical computers. How to achieve general computing of quantum computers, that is, to make quantum computers have Turing completeness similar to classical computers, is still a difficult problem.

Xiao Yi has also thought about this problem, and finally came to the conclusion that the basic performance of quantum computers has not yet reached the level of manufacturing quantum Turing machines.

As for basic performance, it involves a series of other problems, such as materials, basic technology, theory, etc.

In short, don't think about making a quantum Turing machine at present.

He might as well focus on studying other problems, just like now.