Hand rubbing nuclear fusion live in the wilderness

Chapter 392 A New Way of Smelting Allotropes
The audience in the live broadcast room looked curiously at the bottle that Won took out.

It is a non-glass material that looks a bit like plastic, but it is a transparent triangular bottle, which contains more than half of the bottle of light red solution.

【what is this? 】

【Chemicals? 】

[The anchor is on fire, right?Why is it red? 】

[When you get angry, it will turn yellow, and red is uremia (_)]

[Should it be some kind of acid?Used to melt nickel powder? 】

[How did the upstairs know so clearly?Could it be that yours is red? 】

【At least the host must be φ(゜▽゜*)】

[I used to drink too much Red Bull. I drank eight bottles a day, and then my urine was this color. 】

[Eight bottles a day?How stupid are you upstairs? 】

The audience in the live broadcast room were joking and joking.

Han Yuan looked at the barrage on the virtual screen with black lines all over his face.

These netizens are really sand sculpture netizens all the time.

After coughing and drawing the audience's attention, Han Yuan continued:
"The one I have in hand is the solution that will be used later to separate ordinary lattice nickel powder from 'hexagonal closest-packed' lattice nickel powder."

"It is a mixture of various acids such as hydrochloric acid and metachloronitric acid, and various liquids such as cyanide and nickel chloride. It is called a 'hexagonal lattice distinguishing agent'."

"I broadcasted its manufacturing process before, so I won't talk about the details."

"The principle and function of the 'hexagonal lattice discriminator' are quite simple. It uses the difference in solubility of two different lattice nickel powders, the 'common lattice nickel powder' and the 'hexagonal closest-packed' lattice, to separate the two"

"Everyone knows that allotropes are the same element as this element."

"But different allotropes, because their atoms are arranged differently, have different properties of the element."

"For example, the most common carbon, it has many allotropes, such as graphite and diamond."

"Although they are all composed of carbon atoms, many physical properties are very different because of the different arrangement of atoms."

"Whether it is color state, or hardness, or conductivity, density, and melting point, there are big differences."

"In addition, although the property differences between allotropes are mainly manifested in physical properties, there are also differences in activity in chemical properties."

"For example, the two allotropes of phosphorus, red phosphorus and white phosphorus, have fire points of 240 and 40 degrees Celsius respectively, but the products after full combustion are all phosphorus pentoxide."

"The same is true for nickel's ordinary lattice and hexagonal closest-packed lattice. Their atomic arrangements are different. In addition to the differences in physical properties, there are also some differences in chemical properties between the two."

"Using the solution in my hand to separate ordinary lattice nickel powder and 'hexagonal closest-packed' lattice nickel powder uses the difference in solubility between the two."

"This mixed solution of various acids and organic solvents has a strong solubility for nickel powder with a common lattice."

"The nickel powder with the 'hexagonal closest-packed' lattice has a certain resistance in the face of this solvent."

"The short answer is that it doesn't dissolve as quickly."

"Therefore, there is a dissolution time difference between the two, which is the principle that the 'hexagonal lattice distinguishing agent' can separate the two."

Han Yuan's words were very detailed and straightforward, and most of the audience in the live broadcast room understood it, and they immediately felt complacent.

[So that's how it is. 】

[Understood, it is to use the different melting times of the two nickel powders to separate them. 】

[To put it simply, the boiling point of alcohol is 78 degrees and water is 100 degrees. If the two mixtures are heated above 78 degrees, the alcohol will boil and separate from the water at an accelerated rate. 】

[The difficult host explained in such detail this time, I understand it too! 】

[Primary school students can understand it, it's too simple. 】

【Are you feeling complacent now?Have you forgotten how you were abused by the anchor before? 】

[I really hope that the following live broadcasts will be the same as this. I can understand, understand, and learn some new things. 】

[This principle is really simple, why no one on our planet thought of it? 】

[Is this still simple?Don't you forget that the so-called 'hexagonal lattice distinguishing agent' is a mixture of many kinds of acids and organic solvents, and how much time will it take to test it out? 】

The audience in the live broadcast room was excited, and many veterans kept scrolling through the barrage, expressing their understanding.

In fact, after entering the era of electrification, ordinary viewers are often confused about the live broadcast. Even if Won has some explanations, they are not as detailed as this time.

Especially in terms of some black technology, the various professional terms that pop up during the explanation are simply overwhelming, and they cannot be understood at all.

The ordinary viewers in the live broadcast room were excited, as were the scientists and researchers from various countries.

This time, the separation method of ordinary lattice nickel powder and 'hexagonal closest-packed' lattice nickel powder seems to open the door to a new world.

Everyone was amazed that allotropes could still be separated in this way.

This method has excited scientists and researchers from all over the world, and they can't wait to try it out now.

But the problem is that the live broadcast of Korean Won is still going on, and they are reluctant to bear this.

Looking at the various barrages on the virtual screen, Han Yuan smiled and began to process the 'hexagonal lattice distinguishing agent' in his hand. '

Although this method of separation using the different chemical and physical properties between allotropes is good, it still has shortcomings.

Like the nickel powder of the ordinary lattice, the nickel powder of the 'hexagonal closest packing' lattice will also be melted in the 'hexagonal lattice distinguishing agent'.

It's just that its dissolution rate will be much slower, and it will be affected by the external temperature and pressure to a certain extent.

For example, the lower the outside temperature, the slower the dissolution rate of nickel powder with the 'hexagonal closest-packed' lattice in the solvent.

These are all available.

But after all, it is unavoidable that it will also be dissolved in the 'hexagonal lattice distinguishing agent'.

This is the loss, and the loss is actually quite large.

Calculated based on theoretical data.

In one hundred kilograms of mixed nickel powder, if the ordinary lattice nickel powder and the 'hexagonal closest-packed' lattice nickel powder each occupy half, that is to say, each has fifty kilograms.

Then the "hexagonal closest packing" lattice nickel powder separated by this method is less than 35 kg.

Even less.

External factors, dissolution time, solution saturation and dissolution surface, etc. will all affect the final yield.

When Won dilutes the 'hexagonal lattice distinguishing agent' in his hands to an appropriate concentration, the nickel bricks in the grinder are almost finished.

Won put on protective equipment and sorted out the finely ground powder.

Weigh, take the amount, and blend into the diluted medicine.

The amount of medicine and nickel powder should be in one-to-one correspondence.

If the amount of 'hexagonal lattice distinguishing agent' is too much, it will lead to a large amount of dissolution of the 'hexagonal closest-packed' lattice nickel powder in the mixed nickel powder.

However, if the amount of "hexagonal lattice distinguishing agent" is small, the ordinary lattice nickel powder in the mixed nickel powder will not be completely dissolved, which will cause impurities in the final gamma nickel powder, which will affect the quality.

If the ratio is not well controlled, the best way is to use more 'hexagonal lattice distinguishing agent' than mixed nickel powder.

It is best to ensure that the ordinary lattice nickel powder inside will dissolve completely.

Even if part of the special form of nickel powder inside will be dissolved, this will ensure the purity of the final extracted gamma nickel.

Of course, for won, the ratio of solvent and nickel powder is not a problem.

The knowledge information in the mind contains the best ratio that has been found out after countless experiments.

He only needs to optimally deploy and process according to the ratio.

The milled nickel powder is mixed with the 'hexagonal lattice distinguishing agent' with a good dilution ratio.

The container for the two is placed in a device similar to a refrigerator.

This device can regulate the temperature.

Because the temperature will be low, whether it is nickel powder of ordinary lattice or 'hexagonal closest-packed' lattice nickel powder, the dissolution rate will be reduced.

However, the speed of this reduction is actually limited, and the reaction speed of the mixed nickel powder in powder form and the solution is quite fast.

Visible to the naked eye, the reddish solution color is fading rapidly.

Although the temperature is lowered, the nickel brick is ground into powder by the Korean Won, which increases the contact area.

This is impossible.

Because if the nickel brick is whole or simply broken and thrown into the solvent, the dissolution rate is too slow.

The 'hexagonal closest-packed' lattice nickel mixed with ordinary lattice nickel melts together during a long dissolution time.

Although nickel bricks are ground into nickel powder, their dissolution rates are also different because of their different properties.

Therefore, as long as the external conditions and dissolution time are properly grasped, the 'hexagonal closest-packed' lattice nickel can still be preserved.

After the mixed nickel powder was melted into the solvent, Won counted the time with a stopwatch.

When the time came, he quickly poured out the 'hexagonal lattice distinguishing agent' in the container equipment.

After the liquid in the container passes through a white cloth with a dense structure, the 'hexagonal lattice distinguishing agent' which dissolves ordinary lattice nickel drips through the white cloth into the container under the white cloth.

What remains on the white cloth is the separated 'hexagonal closest-packed' lattice nickel.

After waiting for a few seconds to let the liquid on the white cloth drain off, Han Yuan picked up the prepared water gun again and rinsed the 'hexagonal closest-packed' lattice nickel on the white cloth.

This is to remove the "hexagonal lattice distinguishing agent" remaining on the surface of the "hexagonal closest-packed" lattice nickel, so as to prevent it from remaining on it and continue to dissolve, causing unnecessary losses.

After cleaning, the 'hexagonal closest-packed' lattice nickel remaining on the white cloth was collected by Won.

The rest of the mixed nickel powder also passed through this process one by one, separating the ordinary lattice nickel and the 'hexagonal closest-packed' lattice nickel.

Of course, ordinary nickel dissolved in the 'hexagonal lattice distinguishing agent' after separation can also not be wasted.

Through the preparation of potions, the nickel ions inside can be extracted and reused like refining gold.

After the treatment is completed, the separated 'hexagonal closest-packed' lattice nickel is collected by Won and stacked together in a closed container.

The container is vacuumed to prevent the nickel inside from oxidizing too quickly.

On the other hand, Won took some samples and brought them to the chemical laboratory for testing.

Through the optical magnifying glass, it can be clearly seen that there are some potholes on the surface of these fine granular nickel powder particles.

Some are less, some are more.

This is the trace of corrosion by the 'hexagonal lattice distinguishing agent'.

As for why the degree of corrosion is different, it is because the content of ordinary lattice nickel in the original nickel powder particles is different.

Like the nickel powder in the most central area, which is basically composed of 'hexagonal closest-packed' lattice nickel, it will not be corroded too severely in a short period of time.

The outer layer of nickel powder 'hexagonal closest packing' lattice nickel and ordinary lattice nickel are intertwined. There are large and small depressions left on the surface of the particles.

Optical magnifying glass, elemental analyzer, infrared analyzer.
These nickel powder particles used for detection have been passed through various instruments, and the Korean won has been compared strictly according to the standards.

Confirm whether the crystal lattice shape, purity and other conditions of these nickel powders meet the requirements.

It took more than four hours to complete the last inspection on the 'hexagonal closest-packed' lattice nickel, and the Korean won who got the data information also breathed a sigh of relief.

Judging from the current test data, the manufactured 'hexagonal closest-packed' lattice nickel fully meets the conditions and can proceed to the next step.

As soon as the news was announced, cheers erupted in the live broadcast room.

【Brilliant! 】

[Success once, no loss is the anchor's style! 】

[These leftover residues are gamma nickel? 】

[Shouldn't it be?Didn't the anchor say that this is 'hexagonal closest-packed' lattice nickel? 】

['Hexagonal closest-packed' lattice nickel is gamma nickel, which has been separated now, but it will be crystallized into ordinary nickel in the future at room temperature. 】

[The difficulty is how to preserve it stably? 】

[The anchor must have a way, just keep watching. 】

[This thing is really troublesome to make, each step has various restrictions and conditions, once something goes wrong, it is easy to scrap. 】

[But after it is formed, it is awesome. The material that can resist neutron radiation is the only one, and there is no semicolon. 】

[I remember that the most powerful material against neutron irradiation seems to be a special ceramic, but it can't resist a few times of irradiation. I don't know how many times this demon nickel can resist. 】

[It depends on the dose of neutron irradiation. Regardless of the value, talking about the power is a hooligan. 】

[Needless to say the greatest value of this thing, but I wonder if it can be used in other ways? 】

The audience in the live broadcast room were discussing, and they were very interested in the newly produced 'hexagonal closest-packed' lattice nickel.

In particular, this material is still used in controlled nuclear fusion.

This is more eye-catching and attention-grabbing.

(End of this chapter)