Interacting nanotubes for nano communication purposes by (nanoparticles) Nano particle PhD Nano _ Microelectronics
Researcher and author: Dr. ( Afshin Rashid)
Note: The origin of noise in nanoelectronics is currently more in carbon nanotubes based on the functions of nanocommunication and the structure of graphene particles in nanotubes interacting for nano-communication purposes by (nanoparticles) in CNT single-walled carbon nanotubes. And multi-walled CNTs are performed.
Nanomaterials with high surface-to-volume ratio The noise produced by nanoparticles is very attractive because they are very sensitive to surface changes. A representative material of this type is carbon nanotubes, which are rolled sheets of graphene hexagonal lattice with a thickness of only one carbon atom.
A simple nanocommunication device consisting of a carbon nanotube that forms two electrodes. These connecting magnetic particles are exposed to various large molecules, causing some of them to attach to the surface of the carbon nanotube. In nano-telecommunications , different molecules give unique sound signals in relation to the properties of the molecules. The power of interaction between carbon nanotubes and molecules arises from noise signals. In nano-telecommunications, the interaction with electronic nanoparticles based on carbon nanotubes changes the signal generated by the carbon nanotube device following the adsorption of specific single molecules. This is because the adsorbent molecule creates a trap in the carbon nanotube, which conducts it.This means that carbon nanotubes based on carbon nanotubes are very sensitive. And they can detect a unique amount of single molecules. The ability to describe single molecules using highly sensitive nanoelectronics is an exciting prospect for sensors, especially for neural applications and biosensors. The use of audio signals to identify molecular activity (interaction) or (active orbit) is attractive. In nanocommunication and interaction with electronic nanoparticles based on carbon nanotubes, signal detection sensitivity may be increased through the production of controllable noise. These carbon nanotube-based nanocommunications show that it is possible to detect individual molecules through their unique noise particles in current nanocommunication signals. Improved knowledge of molecular origin and interaction with electronic nanoparticles based on noise carbon nanotubes should lead to the development of electronics that use noise to improve their performance rather than destroy it.
Conclusion :
Noise is a low-frequency random oscillation that occurs in many nano-telecommunication devices, including nanoelectronics, environments, and organisms. Noise can blur signals, so it often goes out of electronic and radio transmission.
Researcher and author: Dr. ( Afshin Rashid)
PhD in Nano-Microelectronics