Su Zhe turned on the switch of the light, put the cloth handbag and large water cup in his hand on the desk, took out a blank A4 paper, picked up the pen and quickly wrote on the paper.

Soon, the formulas and data were written all over the A4 paper, and he put down the pen and looked at the contents of the A4 paper, and infinite emotion rose in his heart.

Because of the back and forth vibration of the office door, he connected the XX-hydrogen atom vibration model with the mirror processing of the optical lens lens.

The hydrogen atom absorbs X-rays with a wavelength of 1.25 nm and then releases X-rays with a wavelength of 0.02 nm under a specific environment, thereby displacing the hydrogen atoms.

By taking advantage of this characteristic of hydrogen atoms, it is possible to manipulate hydrogen atoms to vibrate, and use the vibration of hydrogen atoms to drive the vibrations of other atoms to make the mirror surface of the optical lens lens more flat.

A4 is written on the paper is the important formula and data to achieve this process, and next, he needs to make detailed calculations to see the theoretical feasibility of this method.

Su Zhe got up, closed the office door, turned on the air conditioner, and adjusted the temperature to a minimum temperature of 16 degrees.

Fill the big water cup with water, peel off all the sugar paper of the white rabbit toffee, put the pieces of white rabbit toffee neatly, and put the towel next to it.

Ready for this, he looked at the time.

02∶10

In the early hours of Saturday, June 24

He turned off his mobile phone, began to stuff White Rabbit toffee into his mouth, and ate ten at a time with warm boiled water.

Fill the large water glass again.

Sit up straight and start calculating.

The object he chose for processing was an optical lens lens with a negative ion beam for the fifth test.

The lens of this optical lens is mainly made of silicon dioxide, with small amounts of calcium hydroxide, boron oxide, lead oxide, and zinc oxide.

It contains seven elements: silicon, oxygen, hydrogen, boron, lead, zinc, and calcium.

This time, Su Zhe analyzed the material composition and structure of the optical lens lens in more detail.

Such as silica. The structural distribution of calcium hydroxide and so on in the lens, that is, the distribution of hydrogen atoms.

After these calculations, the parameters of the machining environment are calculated.

Such as temperature, vacuum, magnetic field, etc

To do this, you need to calculate the intensity of X-rays with a wavelength of 1.25 nanometers.

This calculation process is very complicated and requires a variety of factors to consider.

Depending on the intensity of X-rays with a wavelength of 1.25 nanometers, the displacement of hydrogen atoms, that is, the intensity of vibration, is also different, and the degree of influence on surrounding atoms is also different.

After these calculations, the next step is to calculate whether the release of X-rays at a wavelength of 0.02 nanometers by the hydrogen atom has an effect on other atoms.

In layman's terms, it is the effect of X-rays with a wavelength of 0.02 nanometers on the lens and processing environment of an optical lens.

At this point, all factors are taken into account to calculate the intensity range of X-rays with a wavelength of 1.25 nanometers.

Intensity here refers to the luminous flux of X-rays with a wavelength of 1.25 nm, which can also be understood as the power of X-rays with a wavelength of 1.25 nm.

In the end, it was found that the power of X-rays with a wavelength of 1.25 nanometers was too large to be produced by existing equipment.

Seeing such a result, Su Zhe stared at the calcium atom.

The vibration of hydrogen atoms and the vibration of calcium atoms are superimposed, which can not only achieve the purpose, but also create the corresponding X-ray light source, which will not be impossible to create because of the power of the light source.

It's just that now the XX-calcium atom vibration model has not been experimentally confirmed, and there is a certain risk.

However, according to the theory, it is completely feasible, and it is determined that the calcium atom absorbs X-rays with a wavelength of 1.36 nanometers and releases X-rays with a wavelength of 0.1 nanometers, and the displacement occurs.

After thinking about it, Su Zhe didn't care so much, and directly pulled the calcium atoms in.

Hydrogen and calcium atoms are used as vibration sources.

Using the same method, the same steps, the calculations were done again.

Of course, this time it was a little more complicated, but it didn't bother him.

Time passed minute by minute, and as he calculated, the smile on Su Zhe's face became thicker and thicker.

After writing down the last parameter on the A4 paper, he jumped excitedly.

It's done!

Through calculations, using the method of double vibration of hydrogen atoms and calcium atoms, the surface surface of the plane mirror can theoretically reach the peak and valley value of surface shape accuracy of 50 femtometers and the surface roughness of 10 femtometers.

It is three orders of magnitude stronger than the peak-to-valley value of 0.12 nanometers of surface accuracy and the surface roughness of 20 picometers processed by Chase Company.

Theoretically, the mirror surface of the curved mirror can reach a peak-to-valley value of 0.5 picometers and a surface roughness of 0.1 picometers.

Seeing such a result, Su Zhe was very excited.

Wiped the sweat from his forehead with a towel, threw the last three White Rabbit toffees into his mouth, and drank some water.

Then we started tidying up.

The speed of sorting is faster.

It is nothing more than the various parameters of the processed optical lens lens, the parameters of the processing environment, the light source intensity of X-rays with a wavelength of 1.25 nm and X-rays with a wavelength of 1.36 nm, the control of the lens processing process, and so on

Organize it by category.

Put these sorted A4 papers into a special folder.

In the end, he gave the technique a name: QG-Diatomic Vibration Technology.

He put the name "QG-Diatomic Vibration Technology" on the cover of the folder, just like the previous XX-hydrogen atom vibration model, XX-calcium atom vibration model, and DYN-ion beam polishing technology.

Looking at the folder of QG-diatomic vibration technology, he found the folder containing the DYN-ion beam polishing technology and the folder containing the XX-hydrogen atom vibration model and the XX-calcium atom vibration model.

Place the three folders on your desk one after the other.

I feel a lot of feelings.

The original purpose was to break through the ion beam polishing technology, and he not only developed the DYN-ion beam polishing technology, but also made him develop the QG-diatomic vibration technology.

The most important is the XX-hydrogen atom vibration model and the XX-calcium atom vibration model, which is a subversive discovery.

The QG-diatomic vibration technique is only part of the application of the atomic vibration model.

Now, what he has to do is wait for the end of the sixth test and inform Bao Zhengyi and Fan Xiaoming of this big surprise.

DYN-ion beam polishing technology is better, the theory is complete, as long as it is implemented in engineering according to the theory.

XX-hydrogen atom vibration model, XX-calcium atom vibration model.

The former is confirmed by the original data, and the latter requires the design of special experiments to verify the correctness of the XX-calcium atom vibration model.

As for the final QG-diatomic vibration technology, as long as the XX-calcium atom vibration model is confirmed by experiments, the QG-diatomic vibration technology has a theoretical basis and can be tried to be realized.

In the end, Su Zhe thought of an important problem, in the QG-diatomic vibration technology, the energy conversion rate of diatomic vibration is particularly low, and most of the energy carried by X-rays with a wavelength of 1.25 nm is converted into X-rays with a wavelength of 0.02 nm.

This means that QG-diatomic vibration technology is a high-energy-consuming technology, but considering the application needs and scenarios of ultra-high-end optical lenses, it is also acceptable to consume more energy.