Nano-telecommunication) micro-vibrations  in current nano-telecommunication signals (PhD in nano-microelectronics)

Researcher  and author: Dr.   (   Afshin Rashid)



Note: It is possible to identify individual molecules through their unique noise particles in current nano-telecommunication 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 instead of destroying it.

Quantum interference or quantum parallelism gives us enormous computing power, especially in source coding, where information about the entire content is required instead of individual inputs. Molecular method is the sending and receiving of information encoded in molecules  , while electromagnetic communication is sending and receiving  electromagnetic radiation from various nano-equipment  . These methods are molecular method and electromagnetic method are among the wireless methods  In the electromagnetic communication, electromagnetic communication between the nano-  sensors is dependent on the development and construction of two major parts, nano-antennas and  transceivers for it  in Mqayas nanotubes, graphene-based antennas to transmit EM waves are  used. Graphene is a very thin monoatomic plate Of limited carbon atoms placed on a crystal lattice  Due to the very low dimensions of nano-sensors, nano-antennas need a very high operating frequency to be usable  However, the use of  graphene greatly helps to solve this problem. 



Nano-devices are connected in frequencies around 1.0 to 10 terahertz. Due to the severe limitations of nano-devices in terms of size and energy, the production of high power signals in the frequency of terahertz is not operational. Therefore, classical communication patterns based on continuous signal communication can not be implemented and for time WNSNs, short-time pulse modulation techniques (OOK-TS: Keying Off-On) are used. These techniques are especially used in cases such as frequency detection systems as well as the Internet of Things. Wave as information carriers similar to classical communications. However, due to the severe shortage of resources and the quantum effects of materials, classical methods can not be applied directly in the field of nanotechnology. Therefore, it is necessary to use new materials and techniques. 



Conclusion : 

It is possible to identify individual molecules through their unique noise particles in current nano-telecommunication 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 instead of destroying it.

Researcher  and author: Dr.   (   Afshin Rashid)

PhD in Nano-Microelectronics