It's just that during the collision, its lifespan ended or it lost the ability to transition, so it was ultimately not captured.

Thinking of this.

Xu Yun was silent for a moment, then walked out of the library.

He took out his phone and dialed a number.

A moment later.

The phone connected, and a voice that immediately sounded very handsome came through on the other end:

"Hello, Xiaoxu?"

"Yes, it's me. Do you have time now, professor?"

"Just came out of the lab, what's up?"

Xu Yun organized his words and said: 𝙛𝒓𝓮𝒆𝔀𝒆𝙗𝓷𝒐𝙫𝒆𝙡.𝒄𝓸𝓶

"Professor, didn't I study a topic on Σ hyperons before? Do you remember?"

The Σ hyperon is one of the more mainstream hyperons at present, with a lifespan of 0.15 nanoseconds and a mass slightly heavier than a hyperon.

Xu Yun's master's thesis was on the energy level effects generated by strong interactions of Σ hyperons, involving aspects of quantum chromodynamics theories.

So very quickly.

Academician Pan's reply came from the other end of the phone:

"That's right, ...oh, I saw the record of you activating the Aurora System, have you made any progress in your research?"

The Aurora involved computational power issues with the server, and the share for each student was limited.

As Xu Yun's mentor, Academician Pan naturally received related notifications, and Xu Yun didn't plan to hide it from him:

"It's like this, professor, when I was researching the Σ hyperon, I suddenly discovered a rather special orbit with some differences in the eigenstate compared to the Σ hyperon."

"Later, I used the Aurora System to simulate and found it somewhat similar to the 4685Λ hyperon recently observed by Academician Zhao."

"So I optimized the simulation for this orbital formula, replacing the Σ hyperon's decay parameters with that of the Λ hyperon, and finally found..."

On the other end of the phone.

Academician Pan was originally tilting his head, holding the phone with his shoulder and ear, while both hands were taking apart a delivery of sanma fish.

But upon hearing Xu Yun's first sentence.

He vaguely realized something and stopped what he was doing.

By the time Xu Yun finished his last sentence, his expression had become much more serious, and he had fully caught up with Xu Yun's line of thinking:

"Xiaoxu, what is the final F?"

"t=0, F=1, in other words, there should be a new particle on that orbit."

After saying that, Xu Yun paused for a moment and added:

"A new particle that can be captured and observed."

.....

Note:

Let's go big, everyone can guess what technology this new particle will lead to.

The information that can currently be disclosed is as follows:

This technology involves not just the Λ hyperon, but also DNA storage technology and the AI system Mimi, as well as the ratio in the last part of the reward formula. (The orbital formula is only the first part of the three parts)

If you guess correctly, I'll post thirty more updates. I don't believe anyone can guess this right?

The theoretical significance of the Λ hyperon actually holds many possibilities.

For example, it could help discover the legendary fifth force, aid in the detection of dark matter and dark energy, and could even facilitate research on neutron stars, among other things.

And in reality, the most direct impact is seen in the phones you and I use.

Currently, all phones use knowledge of quantum theory, because most of the core components of phones use semiconductors, and the performance of semiconductor materials needs to be calculated and optimized based on quantum mechanics.

For example, there is a gap in the PN junction.

In layman's terms, it means the electric potential energy is greater than the kinetic energy of the electron, and under normal understanding, it's impossible for the electron to pass through this gap.

But under the framework of quantum mechanics, it allows electrons a certain probability to transition, a phenomenon known as electron tunneling.

The principle behind Scanning Tunneling Microscope is precisely this. You can see the potential energy fluctuations on the material surface.

Thus deducing the surface structure of the material, ultimately leading to semiconductor development.

For example, currently, Samsung has sold a phone equipped with an Optical Quantum Chip, the Galaxy A Quantum, for over five hundred bucks.

The Optical Quantum Chip is used to generate quantum random numbers, ensuring that encryption algorithms are physically absolutely secure; this is also considered a trend for the future.

Thus, research on microscopic particles is actually closely related to our reality, but because the final product is in a complete form, many of the technologies within face certain information barriers.

And compared to other hyperons.

The Λ hyperon is even more special.

It's an extremely special hyperon, its single-particle depth well in nuclear material is the deepest among all known particles.

To put it simply... oops, in more layman's terms.

It could be considered a crucial fundamental in controlled nuclear fusion.

Therefore, countries currently place very high importance on it, and the annual related funding in major leading countries starts at one to two hundred million.

The vision returns to its original place.

Xu Yun had heard about Academician Zhao's recent observations, with the maximum polarization of the decay case breaking through 26%, a global first.

It's somewhat of a news story of moderate significance.

However, it's important to know that the theoretical significance of the Λ hyperon actually has many possibilities.

For example, it could assist in discovering the legendary fifth force, aid in the detection of dark matter and dark energy, and could even research neutron stars, among other things.

And in reality, the most direct impact is seen in the phones you and I use.

Currently, all phones use quantum theory knowledge since most core components of phones utilize semiconductors, and semiconductor material performance is calculated and optimized according to quantum mechanics.

For instance, there is a gap in the PN junction.

In layman's terms, the electric potential energy is greater than the kinetic energy of the electron, and under normal circumstances, the electron shouldn't be able to cross this gap.

However, within the domain of quantum mechanics, it permits electrons a certain probability to transition, which is known as the electron tunneling phenomenon.

Electron Tunneling Microscopes utilize this principle. You can observe the potential energy fluctuations on a material's surface.

Thus inferring the material's surface structure, ultimately facilitating the development of semiconductors.

For example, currently, Samsung has marketed a phone with an Optical Quantum Chip, the Galaxy A Quantum, priced over five hundred dollars.

The Optical Quantum Chip is used to generate quantum random numbers, ensuring that encryption algorithms are absolutely secure on a physical level; this is also considered a future trend.

Thus, microscopic particle research is indeed closely connected to our reality, but as the final product is a complete form, many internal technologies face particular information barriers.

Compared to other hyperons,

The Λ hyperon is even more special.

It is a particularly special hyperon, and its single-particle potential well depth in nuclear material is the deepest among known particles.

In simple terms... or, to put it plainly.

It's akin to being a crucial foundation in controlled nuclear fusion.

Therefore, countries highly prioritize it, with the annual related funding from major leading nations starting from one to two hundred million.

Returning the vision to its original place.

Academician Zhao's recent observations, which Xu Yun had heard about, had a decay case's maximum polarization breaking through 26%, a global first.

It's somewhat significant news.

But it's important to recognize the theoretical significance of the Λ hyperon actually encompasses many possibilities.

For instance, it might help discover the legendary fifth force, assist in the detection of dark matter and dark energy, and potentially enable research on neutron stars, among other things.

And practically, the most direct impact is observed in the phones we use.

Currently, all phones use quantum theory knowledge because most core components in phones utilize semiconductors, and semiconductor material performance is calculated and optimized using quantum mechanics.

Example, within a PN junction, there is a gap.

Simply put, the electric potential energy is greater than the kinetic energy of the electron; under normal circumstances, the electron can't cross this gap.

However, under the realm of quantum mechanics, it permits a certain probability for electrons to transition, known as electron tunneling.

The principle of the Electron Tunneling Microscope is precisely this; it allows for observing potential energy fluctuations on a material's surface.

Thus deducing the material's surface structure, ultimately facilitating semiconductor development.

For instance, Samsung currently markets a phone with an Optical Quantum Chip, the Galaxy A Quantum, priced over five hundred dollars.

The Optical Quantum Chip generates quantum random numbers, ensuring encryption algorithms' absolute physical security; this is also considered a future trend.