Su Zhe turned on the light switch, put the cloth handbag and large water bottle on the desk, pulled out a blank A4 paper, picked up a pen and quickly wrote on the paper.
Soon, formulas and data were filled up on the A4 paper. He put down the pen and looked at the contents on the A4 paper, feeling infinite emotion in his heart.
Just because the office door vibrated back and forth, he connected the XX-hydrogen atom vibration model with the mirror processing of optical lens lenses.
Hydrogen atoms absorb X-rays with a wavelength of 1.25 nanometers under a specific environment, and then release X-rays with a wavelength of 0.02 nanometers, causing the hydrogen atoms to shift.
Using this characteristic of hydrogen atoms, we can control the hydrogen atoms to vibrate, and use the vibration of hydrogen atoms to drive the vibration of other atoms to make the mirror surface of the optical lens smoother.
What is written on the A4 paper is the important formulas and data for realizing this process. Next, he needs to make detailed calculations to see the theoretical feasibility of this method.
Su Zhe stood up, closed the office door, turned on the air conditioner, and adjusted the temperature to the lowest temperature of 16 degrees.
Fill the large water cup with water, peel off the wrappers from the pounds of White Rabbit toffee, place the pieces of White Rabbit toffee neatly, and put the towel next to it.
Having made these preparations, he looked at the time.
02:10
Early morning of Saturday, June 24th
He turned off his cell phone and started stuffing White Rabbit toffee into his mouth, consuming ten of them at a time with warm water.
Fill the large water glass again.
Sit upright and start calculating.
The object he chose to process was the fifth test, an optical lens lens processed with a negative ion beam.
The lens of this optical lens is mainly made of silicon dioxide, with a small amount 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 optical lens lenses in more detail.
Such as silica. The structural distribution of calcium hydroxide, etc. in the lens is the distribution of hydrogen atoms.
After calculating these, calculate the parameters of the processing environment.
Such as temperature, vacuum degree, magnetic field, etc.
To do this, we need to calculate the intensity of X-rays with a wavelength of 1.25 nanometers.
This calculation process is very complicated and needs to consider many factors.
The intensity of X-rays with a wavelength of 1.25 nanometers is different, and 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 are completed, we then calculate whether the X-rays released by hydrogen atoms with a wavelength of 0.02 nanometers have any impact on other atoms.
In layman's terms, it is the impact of X-rays with a wavelength of 0.02 nanometers on the lenses and processing environment of optical lenses.
At this point, all factors are taken into consideration to calculate the intensity range of X-rays with a wavelength of 1.25 nanometers.
The intensity here refers to the luminous flux of X-rays with a wavelength of 1.25 nanometers, which can also be understood as the power of X-rays with a wavelength of 1.25 nanometers.
In the end, it was discovered that the required power of X-rays with a wavelength of 1.25 nanometers was too large, and existing equipment could not produce such high-power X-rays.
Seeing such results, Su Zhe focused on calcium atoms.
The vibration of hydrogen atoms and the vibration of calcium atoms, superimposed, can not only achieve the purpose, but also create a corresponding X-ray light source, which will not be unable to create due to the power of the light source.
It's just that the XX-calcium atom vibration model has not been experimentally confirmed, and there are certain risks.
However, it is completely feasible according to theory. It is determined that calcium atoms absorb X-rays with a wavelength of 1.36 nanometers, release X-rays with a wavelength of 0.1 nanometers, and undergo displacement.
After thinking about it, Su Zhe didn't care so much and directly pulled the calcium atom in.
Use hydrogen atoms and calcium atoms as vibration sources.
Calculated again using the same method and steps.
Of course, this time it was more complicated, but it was not a problem for him.
Time passed by, and with the calculation, the smile on Su Zhe's face grew stronger and stronger.
After writing the last parameter on the A4 paper, he jumped up excitedly.
Done!
Through calculation, using the method of double vibration of hydrogen atoms and calcium atoms, the plane mirror surface can theoretically achieve a peak-to-valley surface accuracy of 50 femtometers and a surface roughness of 10 femtometers.
It is three orders of magnitude better than the peak-to-valley surface accuracy of 0.12 nanometers and the surface roughness of 20 picometers processed by Zeiss.
In theory, the surface of the curved mirror can achieve a peak-to-valley surface precision of 0.5 picometers and a surface roughness of 0.1 picometers.
Seeing such results, Su Zhe was very excited.
He wiped the sweat from his forehead with a towel, threw the last three White Rabbit toffees into his mouth, and drank some water.
Then start organizing.
The sorting speed is very fast.
It is nothing more than various parameters of the processed optical lens, parameters of the processing environment, light source intensity of X-rays with a wavelength of 1.25 nanometers and X-rays with a wavelength of 1.36 nanometers, lens processing process control, etc.
Organized into categories.
Put these organized A4 papers into special folders.
Finally, he gave this technology a name: QG-Dual Atomic Vibration Technology.
He wrote the name "QG-Dual Atom Vibration Technology" on the cover of the folder, the same as the previous XX-Hydrogen Atom Vibration Model, XX-Calcium Atom Vibration Model, and DYN-Ion Beam Polishing Technology.
Looking at the QG-dual atom vibration technology folder, he found the folder containing DYN-ion beam polishing technology and the folders containing XX-hydrogen atom vibration model and XX-calcium atom vibration model.
Place the three folders on your desk.
I feel so many things in my heart.
The original purpose was to make a breakthrough in ion beam polishing technology, and he continued to work on it. Not only did he develop DYN-ion beam polishing technology, but he also developed QG-dual atom vibration technology.
The most important ones are the XX-hydrogen atom vibration model and the XX-calcium atom vibration model. These are disruptive discoveries.
QG-Dual Atom Vibration Technology is only a partial application of the atomic vibration model.
Now, what he has to do is wait for the sixth test to end and inform Bao Zhengyi and Fan Xiaoming of this big surprise.
DYN-ion beam polishing technology is better, and the theory is complete. It only needs to be implemented in engineering according to the theory.
XX-hydrogen atom vibration model, XX-calcium atom vibration model.
The former is confirmed by original data, while the latter requires the design of special experiments to verify the correctness of the XX-calcium atomic vibration model.
As for the final QG-dual atom vibration technology, as long as the XX-calcium atom vibration model is experimentally confirmed, the QG-dual atom vibration technology will have a theoretical basis and can be attempted to be realized in engineering.
Finally, Su Zhe thought of an important issue. In QG-diatomic vibration technology, the energy conversion rate of diatomic vibration is particularly low. Most of the energy carried by X-rays with a wavelength of 1.25 nanometers is converted into X-rays with a wavelength of 0.02 nanometers. .
This means that QG-dual atom vibration technology is a high-energy-consuming technology, but considering the application requirements and scenarios of ultra-high-end optical lenses, it is acceptable to consume more energy.
