Wave propagation analysis of thermoelastic functionally graded nanotube conveying nanoflow

As a hollow cylindrical structure, a nanotube has potential to convey nanoflow, which has opened up a field of research. Functionally graded nanotube as a designable structure with continuous variation of material properties can perform better than uniform nanotube, especially in physical field without introducing large stress concentration. In this article, we take the thermal effect into account and investigated the wave propagation characteristics of functionally graded material nanotube conveying nanoflow. In particular, we compared the effects of different kinds of volume fraction function and also the cases of uniform and nonuniform temperature variation. According to the numerical results, we can conclude that as we decrease the exponent n of the volume fraction function, the system is enhanced and larger enhancement can be observed in the case of the power volume fraction function. In addition, there is a positive correlation between the stability and both the temperature variation and the nonuniformity of temperature variation.

Automated summary

This article investigated the wave propagation characteristics of functionally graded nanotubes, finding that a smaller exponent n in the volume fraction function leads to a better system performance. Additionally, there is a positive correlation between stability and both temperature variation and nonuniformity of temperature variation.