- Oligophenylene vanillin nano wires section
The role of silicone wafers in the propagation of Oligophenylene vanillin nanowires
Researcher and author: Dr. ( Afshin Rashid)
Note: Silicone wafers for biological applications, silicon is similar to glass, and this makes it a suitable support for the growth and/or nanoparticle mounting of Oligophenylene vanillin nanowires . For nanoelectronics applications, it is an ideal sample substrate for small nanoscale particles due to its low background signal and highly polished surface.
Silicon wafer substrates can be used for sample substrates, microfabrication, substrates for Oligophenylene vanillinnanowires, or biological substrates. A useful flat substrate of silicon wafer particles linked with nanowires and for biological applications, Si (silicon wafer) has properties similar to glass and can be used to mount or grow Oligophenylene vanillinnanowire particles. . It can be easily removed or used as a whole wafer for propagation of Oligophenylene vanillin nanowires Silicon nanowire arrays or SiNWs are vertical arrays of silicon nanowires on a flat crystalline silicon wafer substrate. These Oligophenylene vanillin nanowires are fabricated by a catalytic oxidation and dissolution of Si in the presence of metal catalyst nanoparticles—a self-organized process commonly known as silicon wafer-assisted metallo -chemical enhancement. .
The processes of propagation of Oligophenylene vanillin nanowires on silicone wafers make Si Nanowire arrays more reproducible and uniform, and allow the properties of Oligophenylene vanillin nanowires to be adjusted . to be The propagation process of nanowires always involves the deposition of a metal and bonding in a solution containing hydrofluoric acid (HF) and an oxidizer. Silicon is produced only where metal nanoparticles touch silicon, as a result of electrochemical reactions with the help of nanoparticles, as silicon is carried, the nanoparticles move into the resulting nanoparticles. Since silicon is only locally doped, this process can lead to very high aspect ratio features in Oligophenylene vanillin nanowires .
Conclusion:
Silicone wafers For biological applications, silicon resembles glass, which makes it a suitable support for growth and/or nanoparticle mounting of Oligophenylene vanillin nanowires . For nanoelectronics applications, it is an ideal sample substrate for small nanoscale particles due to its low background signal and highly polished surface.