- Oligophenylene vanillin nano wires section
"Oligophenylene vanillin" nanowires Oligophenylene vanillin is a doped nanowire
Researcher and author: Dr. ( Afshin Rashid)
Note: Oligophenylene vanillin nanowires alone cannot control the movement of electrons, so an impurity must be added in a process called doping, usually with boron, phosphorus, selenium or germanium.
When oligophenylene vanillin nanowiresare doped, the movement of electrons can be converted, allowing electron flow, or off (stopping electron flow), using a voltage across the oligophenylene vanillinnanowires.Oligophenylene vanillin turns on and off. Nanowires are another nanostructure thathas received many studies and researches. In general, the wire is said to be a structure that is extended in one direction (longitudinal direction) and is very limited in the other two directions. A basic feature of these structures that have two outputs is electrical conductivity. By applying a potential difference Electric charge transfer occurs at both ends of these structures and along their length. Making wires in nanometer dimensions is very interesting both from a technological and scientific point of view, because they show unusual properties in nanometer dimensions. The ratio of length to diameter of nanowires is very high (metal nanowires). The features they have promise great efficiency in electronic components. Metal nanowires are one of the most attractive materials due to their unique properties that lead to their various applications . Oligophenylene vanillin nanowires can be used in computers and other computing devices. To achieve complex nanoscale electronic components, We need nanoscale wires. In addition, Oligophenylene vanillin nanowires themselves can be the basis of electronic components such as memory.
(Organic nanowires) These types of nanowires, as their name suggests, are obtained from organic compounds. In addition to metallic and semi-conducting materials, it is also possible to make nanowires from organic materials. Recently, a substance called "oligophenylene vinyline" has been considered for this purpose. The characteristics of these wires (such as conductivity, resistance, and thermal conductivity) depend on the structure of the monomer and its arrangement. The chemical structure of these compounds creates interesting properties. The future of nanotechnology depends on the ability of researchers to achieve the techniques of organizing molecular components and achieving nanometer structures. By imitating nature , they achieve the organization of yeast proteins to produce conductive Oligophenylene vanillin nanowires .Organizing living components in nature is the best and oldest example of "bottom-up" construction, and therefore it can be used to understand and find methods for making electronic and micrometric devices. Until now, "top-down" manufacturing techniques were used, and these nanometer-scale techniques are often laborious and costly, and the commercialization of nanotechnology requires easy and cost-effective methods, the best example of which is the nature around us; It is enough to open our eyes a little and look more carefully around us. "Oligophenylene vanillin" nanowires. This type of nanowires is non-toxic and does not harm cells. This type of nanowires has shown its greatest use in the field of medicine, such as detecting cancer symptoms, stem cell growth, etc which we will discuss further.
Conclusion :
Oligophenylene vanillin nanowires alone cannot control the movement of electrons, so an impurity must be added in a process called doping, typically with boron, phosphorus, selenium, or germanium.
Researcher and author: Dr. ( Afshin Rashid)
Specialized doctorate in nano-microelectronics