Biotechnology and carbon drain.

Biotechnology and carbon drain. 

Making artificial diamonds by using volcanic temperature.

What if we would store the carbon, what is released to the air as the form of artificial diamonds, in the chambers, what is made deep underground, where they can benefit the volcanic temperature. That is a very interesting method, for solving the problems, which is caused by carbon dioxide, which is released to the air. 

Can store the carbon dioxide in the form of artificial diamonds offer the change to create a stable solution for the carbon dioxide problem? This solution needs very much energy but in theory, the reaction chamber can create in the deep cave and the volcanic heat can benefit in this process. The cave would be filled with high-pressure carbon dioxide gas, and the volcanic temperature will make the forming of diamonds possible. 

In some very futuristic solutions the carbon, what is released from the industry would be turned to the artificial diamonds in the chambers, where the oxygen has been removed. In those reaction chambers, the carbon would be turned to its crystallized form, which is stable. Then those diamonds can be used as sand. 

Cells and vegetables are fascinating tools for removing carbon from the air, but the carbon is only storing in the structures of vegetables, which means that they are offering only a temporary solution for carbon dioxide problems. And when those things die, they are releasing carbon back to the atmosphere or water, where are forms of carbon acid. 

And this makes very difficult to find a stable location for carbon dioxide. We cannot dump carbon dioxide into water, or we cannot send that stuff to the Sun, and that's why there must find some other way to handle that gas. If we will dump carbon dioxide into water, that would turn to carbon acid, and this thing would start the acidification process also in oceans. 

There are no limits in biotechnology

Biotechnical structures and solutions have no limits. There is a possibility to use fungus or rather saying it's a thread as the small-sized tubes and even particle accelerators. The idea is that the thread would pull straight, and laser rays would shoot through that structure, which makes a hole in it. Then the internal organs would pull out and the tube is ready. Then the structure would crude to its form, and then the magnets will pull around that thing. 

I don't know does that thing operates perfectly, but there is a possibility to make the cheap nanotechnical structures by using this kind of technology, and of course, a thread would use as supporting framework and the miniaturized tubes would pull over this structure. This is one of the things, where the researchers can benefit fungus, but that organism is not the only thing, that can benefit in the biotechnology.

The thing in the fungus is that it is making very long threads, which can pull empty, and that thing can be used to create a new type of canvas. The biological material allows making many things naturally and environmentally friendly way. The thing is that fungus can also store carbon dioxide, but another problem is that when an organism is dying, the carbon dioxide will be released to the air. 

This is the major problem with all carbon drains, which are invented. In the next part, I will write one very interesting solution to the problems, which are caused by carbon dioxide. And one of those solutions is to create very large-scale reaction chambers, which can turn the carbon dioxide into the crystallized form.