Micro-vibrations in Current Nanocommunication Signals
Afshin Rashid
Abstract
: It is possible to identify individual molecules through their unique noise particles in current nanocommunication signals. Improved knowledge of the molecular origin and interaction of nanoparticle-based carbon nanotube-based electronic noise should lead to the development of electronics that use noise to improve their performance rather than degrade it. Introduction :Quantum interference or quantum parallelism gives us enormous computational power, especially in source coding, where information about the entire content is needed instead of individual inputs. Molecular communication is the sending and receiving of information encoded in molecules , while electromagnetic communication is the sending and receiving of electromagnetic radiation from various nanoscale devices . Of these methods, molecular communication and electromagnetic communication are considered wireless methods. In electromagnetic communication, electromagnetic communication between nanosensors depends on the development and fabrication of two important parts, the nanoantenna and its associated transceiver . At the nanoscale, graphene-based antennas are used to transmit EM waves. Graphene is an extremely thin single-atom sheet of confined carbon atoms arranged on a crystal lattice . Due to the extremely small dimensions of nanosensors, nanoantennas need to operate at very high frequencies to be useful. However, using graphene helps to solve this problem to a great extent.