A Comparative Buckling Analysis of Silicon Carbide Nanotube and Boron Nitride Nanotube

Year 2016, , 99 - 107, 28.12.2016

Kadir Mercan

https://doi.org/10.24107/ijeas.281475

Cited By: 2

Abstract

The popularity of nanodevices is gaining a vital importance nowadays.
These supersmall sized devices started to be used in human body as in
computers. The first using of medical nanotechnology is to deliver of
medications with the hope that ‘magic bullet’ chemotherapy to eradicate tumor
cells with lower systemic toxicity. Carbon nanotubes are widely used in
nanotechnology and many works have been done about it. With the science always
need better materials with better properties, scientist have developed Carbon
nanotubes to Silicon carbide nanotubes. On the other hand, another king of
nanotube with better stability properties than Carbon nanotubes is Boron
nitride nanotube. In this work, the stability of the Silicon nanotube and Boron
nitride nanotubes are investigated and compared in buckling case. The stability
of these nanotubes have an important role since it is used in high-tech
equipment and started to be implanted inside of human body. In this article,
the buckling analysis SiCNT and BNNT is investigated by using Euler-Bernoulli
beam theory for different boundary conditions. Results are presented in figures
and table.

Keywords

Silicon carbide, Boron nitride, nanotube, buckling, Euler-Bernoulli

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