What do bacteria sound like? (Bacterial drum can use for making complicated nanomachines)

A graphene drum can use to make the bacterial soundtrack. That thing might not seem anything else than some kind of nerd thing. That they can publish on YouTube.

But the graphene drum can use to make the real things. Sound waves are the pressure impulses that can move objects. The graphene drums and bacteria can use to transfer parts for the nanomachines. The problem with nanomachines is to create a system that can hold their parts long enough that they can take their part in the entirety. 

The bacteria that are in that graphene drum can equip with magnetic crystals. And the magnetic field can use to turn that bacteria in the wanted direction. Many of the nanomachines are operating in liquid. So the bacteria and graphene drum can use for making the complicated structures on a molecular scale. 

The magnetic systems allow moving nanomachines where is iron. But with non-magnetic molecules must be found some other method to move them. And one of those methods is the sound waves. That system is suitable if the nanomachine will be made to operate in the liquid. 

The problem with complicated nanomachines is that their parts are a little bit too heavy for optical tweezers or crossing laser rays. The pressure tweezers are too heavy tools. When the small- molecular-size complicated structures must position in the right place. The graphene drums can use as movers and acoustic tweezers.

Putting four graphene drums in the right position makes it possible to put sound waves crossing at the right point. Then that allows anchoring of the molecule at the right point. The problem with the nanomachines and especially in the protein-based nanomachines is that. Their shape means lots of their actions. The system that moves those proteins must keep them in the perfect shape. 

Sources:

https://scitechdaily.com/what-do-bacteria-sound-like-bacterial-soundtracks-revealed-by-nanotechnology/

https://artificialintelligenceandindividuals.blogspot.com/

  

 The new nanotechnology needs miniaturized microelectronics. 

The bottleneck in the interaction with nanomachines and quantum computers is the interface. Computer keyboards and screens are using binary systems. And that means the development of binary systems is also continuing. Artificial intelligence is the best tool for controlling nanomachine swarms. 

But those systems require powerful computers. And another thing is that the nanomachines are also required internal and well-protected computers. Screens and keyboards are needed to send commands to nanomachines through the quantum system. 

Development of the new quantum systems is not enough. If we want to use quantum computers things like screens and keyboards are the bottleneck for interaction between quantum computers and humans. When we are developing new quantum systems we must load information to the quantum systems. And for that kind of duties is needed to develop more and more powerful binary computers. 

The quantum systems are large-size and if we want to use them to control things like nanomachines. We must realize that the nanomachine can use WiFi to communicate with the quantum systems. But the data that the nanomachine sends and receives must decode to the quantum system. 

The quantum computer can interact with nanorobots by using the internet. But the problem is that those systems use so different architecture that there must be decoders and coders between nanomachine and quantum systems. Also if we are thinking of things like submarines that can swim in our blood vessels those systems require control software and so small computers that they are fitting in the small body. 

Intelligent technology means that the system requires less energy in the physical mechanics. But otherwise, if we want to make the intelligent parts in microchips. Controlling that kind of system requires more powerful computers inside the machine than the dummy technology. But the problem is that the power source of those systems must be extremely small. 

Or electricity must transfer to those miniaturized systems by using radio waves. The antenna would induct that energy into the systems of the miniature robots. But the problem with miniaturized computers can overheat. 

Another version is to use the miniaturized quantum-radio system. Which is using superpositioned sand entangled particles to control the "radios" that are used to aim the submarine or some other nanorobot. 

The superpositioned and entangled particles are also protecting data from turbulence. If there are some unpredicted errors the nanomachine loses its accuracy. Those nanomachines are the next-generation tools for the surgeon and they can open vessels in the human body. 

When the quantum entanglement hits to receiver it inducts power into it. The use of quantum entanglement guarantees high accuracy in data transportation. Also, energy is always at the right level. If the energy level is too high, that means the nanocomputer will overheat. 

https://newatlas.com/physics/new-distance-record-quantum-entanglement-light-matter/

https://scitechdaily.com/fundamental-discovery-used-to-turn-nanotube-into-tiny-transistor-25000x-smaller-than-width-of-a-human-hair/

https://scitechdaily.com/revolutionary-new-intelligent-transistor-developed/

https://en.wikipedia.org/wiki/Nanosubmarine

Image:http://news.bbc.co.uk/2/hi/science/nature/2135779.stm

https://networkedinternet.blogspot.com/