Nano-electrical structure of hybridization (metal nanotube) and reaction with hydrogen gas and fluorine (based on nano-microelectronics) (educational-research doctorate)
Researcher and author: PhD student Afshin Rashid
Note: In the electrical structure of hybridization (metallic nanotube) reacting with hydrogen gas and fluorine, by entering SP3, it converts the electrical structure of metallic nanotube hybridization into semiconductor.
These reactions sometimes damage the walls of the nanotubes, resulting in the formation of amorphous carbon or graphite layer structures. With the hydrogenation of single-walled nanotubes, the semiconductor nature of SWCNTs increases at room temperature. Strong plasma or high temperature reaction etching the wall of metal nanotubes. That semiconductor SWCNTs are not harmed. Therefore controlling the reaction conditions is very important. In nanotubes, reaction with methane plasma eliminates metal SWCNTs without destroying semiconductor SWCNTs. The method uses nano-molecular-weight hydrogen plasma in which hydrogen plasma is used to convert metal SWCNTs to semiconductor SWCNTs, in which case the nanotube walls are not destroyed and etched. These reactions occurring in the gas phase lead to the in situ, large-scale fabrication of TFTS and FETS with semiconductor nanotubes, which is crucial for commercializing high-efficiency nanotube-based equipment . By selecting the appropriate reactant gases, this method can also be used for selective reactivity with semiconductor nanotubes. With the reaction of SWCNTs SO3 as under neutral gas in the presence of gas; the reactive gas inside the furnace at 400◦C, the semiconductor nanotubes preferably react with the gas . The nanotubes are then heated to 900 ° C to recover the defect metal nanotubes . This process is an easy way to enrich the nanotube sample Metal nanotubes. Mass production of metallic nanotubes can be achieved by more precisely controlling the reaction conditions and eventually increasing the scale of its production costs including conductive films and transparent electrodes.
In general, based on the rate of reaction, the electrochemical covalent selectivity of metal nanotubes can be divided into two groups:
1. First, the nanotube metal to a semiconductor, turn that off of the type of metal used and end the nanotube metal is the first reaction along with the establishment of the electron and the loss of symmetry and a dash of energy at the Fermi level nanotube metal Creates.
2. The second reaction conjugate all systems into a series of smaller aromatic compounds through the open CC bonds in the structure of nanotubes makes. The end result of both modes is to obtain semiconductor nanotubes that are suitable for the manufacture of nanoelectronic devices .
In selective covalent reactions, the concentration of the reactant is always important. And when the reactant concentration is high , both types of nanotubes are affected by the reaction . For example, in the case of FETS, increasing the reactant concentration reduces the Off current and thus increases the Off / On ratio to more than 105. On the other hand, it reduces the severe mobility reaction , which is another important parameter for electronic equipment. Therefore, there must be a balance between the rate of reaction progress and the final efficiency of the equipment.
Conclusion :
There are several drawbacks to covalent methods . First of all, most nanotubes become functional and, as a result, the electronic structure of SWCNTs is defective. Second , it is difficult to purify the product from amorphous carbon due to the strong reaction . Most importantly, there is no covalent reaction after which the nanotube (m, n) can be purified individually.
Author: Engineer Afshin Rashid
PhD student of Nano-Microelectronics at Islamic Azad University, Science and Research Branch, Tehran