It can also drive research and development in related fields, and also said some official words such as 'let the world see the domestic technical strength'.

Afterwards, several scholars came on stage to give speeches in their respective fields.

Wang Hao kept listening, but later found that the demonstration meeting was not interesting. It was just a lot of scholars discussing how to implement the project. However, in fact, because the technology was not yet mature and the amount of money consumed was too large, it was unlikely to be passed in a short time.

When the morning report was over, he was ready to leave.

Liao Guangyuan noticed Wang Hao, walked over to talk to him, and asked, "Professor Wang, what do you think of this project?" He hoped to gain Wang Hao's support.

Wang Hao is the top mathematics expert and is very influential in the eyes of senior management. If the project can get Wang Hao's support, the possibility of approval will be greatly increased.

Wang Hao hesitated for a moment and then said, "Academician Liao, I think there is no point in constructing a high-temperature superconducting maglev train in a short period of time."

"Why?" Liao Guangyuan frowned.

Others nearby also looked over.

Wang Haodao said, “The scale of investment is too large, operating expenses are very high, and losses will definitely continue, etc.”

He finished speaking in one breath, and then said, "I believe that other people must have mentioned the cost, maintenance, etc., so I will give another reason."

"Technology!" Wang Hao said with certainty.

Liao Guangyuan immediately said, "We have created a high-temperature superconducting maglev train."

Wang Hao shook his head. He took out his mobile phone from his trouser pocket and showed it to others, "Everyone knows about mobile phones. Ten or twenty years ago, we couldn't even imagine today's mobile phones. Big screens, finger operations, all kinds of

Needless to say about the function.”

The others nodded as they listened.

Wang Hao continued, "It's the same now. We can't imagine what superconducting technology and magnetic levitation technology will look like ten years from now."

"The investment for such a project is tens of billions, and the construction time span will be at least five years. What if the technology has developed greatly by then?"

“My previous investment will be in vain!”

Liao Guangyuan smiled and shook his head, "Professor Wang, I know you are also engaged in research on superconductivity, but you may not know much about it. Compared with thirty years ago, the technology in the field of superconductivity has hardly changed now."

"The theory is still the same theory, the material changes are also very small, and a temperature below 100K is still required."

"Similarly, the magnetic levitation technology is still the same one we bought from Germany. Even other countries have no breakthrough research..."

The others nodded as they listened.

Wang Hao smiled and said, "The past does not represent the future. Maybe superconducting technology will soon usher in rapid development?"

After he finished speaking, he did not continue the conversation, but turned and left the venue.

…

Wang Hao can be considered a newcomer in the field of superconducting research. He applied for a large-scale project by replicating foreign experiments.

That's all.

So his words won't have much impact.

The glorious period of breakthroughs in superconducting technology was in the 1980s, when American scientists Bernoz and Muller discovered that a barium lanthanum copper oxide began to superconduct at 35K.

This was a historic breakthrough, for which Bernozzi and Muller won the Nobel Prize in Physics, and which set off a new upsurge in superconducting research.

At that time, more than two hundred experimental groups around the world participated in the superconducting research competition, and the news media reported overwhelmingly on the progress of superconducting.

After a long period of research, it was found that there was no qualitative breakthrough, and the enthusiasm for superconducting research and development passed away.

Many of the top superconducting experts in China today came from that era. They may have been unknowns at the time, but later they participated in some research and discovered some new superconducting materials, and gradually became famous.

Wang Hao is still a newcomer in the field of superconductivity, but he doesn't care what others think, because his research direction is different from the conventional field.

He just said what he thought.

After returning to Xihai University, Wang Hao went to the physics laboratory and gathered core staff to talk about funding and follow-up research issues.

Everyone else also cheered up.

Now that the new equipment is being debugged, we only need to wait for funds to be allocated before we can continue with subsequent experiments.

Wang Hao's arrangement for the experiment is to use at least three kinds of elemental metals as materials to conduct superconducting alternating current gravity experiments, and to examine the parameters in the experiments in detail.

This kind of research is easy to say, but very complicated to do.

The superconducting critical temperature of elemental metals is very low. The superconducting critical temperature of relatively high lead and technetium is only 7K or 8K.

Most of the critical temperatures of some other superconducting metals are less than 1K.

To create such a low temperature requires experimental coordination, which is very difficult. It requires the use of a large amount of high-pressure liquid helium, and the experimental design requirements are also higher.

At the same time, more funding will be invested.

He Yi made a simple calculation and curled his lips when he looked at the numbers, "Even with new equipment, an experiment will cost at least three million."

Wang Hao didn't care, and did some calculations, "Three million at a time, we have 150 million in funds, and can do fifty experiments."

He Yi was stunned when he heard this. He gave a thumbs up for a long time, "...hao!"

Wang Hao couldn't wait any longer.

Previous research has established a geometric framework for microscopic morphology, and the follow-up step is to conduct experiments and record data. As long as there is sufficient data support, the framework can be improved.

After that, the relationship between microscopic morphological stability and excited superconducting temperature can be found.

This correspondence coefficient is very critical!

Very important!

Just like the coefficients of many physical laws, such as the universal gravitational constant, the gravitational force between two planets can be calculated through the universal gravitational constant and formula.

The current coefficient is used to calculate the superconducting critical temperature of elemental metals, or 'element elements'.

As long as it can be researched, it will definitely be a major progress in the field of superconductivity and trigger a new round of superconductivity boom in the near future.

Wang Hao couldn't help but think of his conversation with Liao Guangyuan.

future?
Chapter completed!