Quantum computers are not the only thing, that quantum technology can offer. Quantum entanglement offers a great tool for a new type of extremely accurate scanning microscopes, what are hovering electron, single-photon, or even quarks over the layer, and that kind of systems are the most accurate things, what we can ever imagine.
If we are thinking that we are using the superpositioned and quantum entangled particles for scanning the surfaces, there is no limit for the range of that thing. So the by using the superpositioned particles the microscope can scan the surfaces theoretically from the range of kilometers, and separate individual atoms from that layer. This is one of the versions of the new way to use quantum entanglement and superposition.
But the quantum entanglement and superposition can be used for many other purposes than just scan surfaces. The quantum entanglement makes it possible to create a quantum version of a circular saw. That system can separate a single covalent bond from the molecules, and that thing allows connecting more atoms in the molecular structure. And that thing makes it possible to create molecules, that have not existed in nature.
The same systems can move individual atoms in the structure, and that makes it possible to move the place of the functional groups in the molecular structures. The things like replacing a single carbon atom in the structure of methane molecule (CH⁴) by using fullerene (C⁶⁰) make the (C⁶⁰H⁴) molecule theoretically possible to make. The fact is that the ion connectors of the carbon molecule must be neutralized, that the fullerene ball is taking just those four hydrogen atoms. The thing is that fullerene has the ability, that acts as a single carbon atom.
The acoustic tweezers can move a single base molecule for the structure of synthetic DNA
When we are making nanomachines like bacteria, what is destroying the cancer cells, that thing requires the ability to form the new synthetic DNA, but the problem is, how to move a single molecule in this structure. Lasers can smash the complicated molecular structure of DNA to pieces. And that means there is required some other systems, which are lower energetic than some laser rays. One version is to use the combination of the acoustic tractor beams and ion clouds, which can be used to put the base molecules in the right places.
The laser rays can cut the DNA in the absolute right position, and the system must only detect, which point is the functional point, where engineers want to affect. The system can aim by using a combination of different types of microscopes. Similar systems, which are used in scanning tunneling microscopes can push and pull individual base molecules and atoms in the structure. But the problem is how to move the single base molecules to the right point that the acoustic or electromagnetic styluses can move it like tweezers.
The tractor beam will pull the base molecules up and it will be ionized and the ion cloud can move them to the right places. The base molecules are just hanging below the ion cloud, and if that thing is working perfectly, that makes it possible to create the synthetic base pairs. And the ability to affect a single base molecule gives new accuracy to the system.
Quantum technology allows to make the new type of chemistry, and one thing, where this technology is capable is to create synthetic DNA and RNA molecules. Moving a single molecule in those structures is difficult and that thing requires something, that can move molecules but what is enough low energetic, that is not breaking the molecular structures of the DNA.
Creating the master-DNA is the most difficult part of the process. When the DNA molecule is created, it's quite easy to inject into the nucleus of the cell. The original DNA is just removed from the cell, and then the synthetic DNA will inject into bacteria or another cell. That DNA turns the bacteria into a chemical factory or it allows to use of bacteria, which ability to make descendants is terminated as medicine.
The bacteria can travel to the tumor, and then start to destroy those harmful cells by using antibodies. Then the bacteria will be terminated, when its mission is over. So by using synthetic genomes, the lifetime of the bacteria can determinate very accurately, and that allows the use of them as medicine.
Image:()http://webhome.phy.duke.edu/~hsg/264L/images/stm.jpg
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