Wave dispersion characteristics in lipid tubules considering shell model based on nonlocal strain gradient theory

In this paper, wave dispersion analysis of lipid tubules is presented by using the first-order shear deformation (FSD) shell theory. The small-scale effect is revealed explicitly based on the nonlocal strain gradient theory (NSGT). Different types of lipid tubules with size-dependent material properties are taken into account. Hamilton?s principle is utilized to derive the equations of wave motion. The analytical solutions of phase velocity and wave frequency of propagated waves are obtained. In addition, detailed investigations are implemented to highlight the effects of the types of lipid tubules, the longitudinal and circumferential wave numbers, the material length scale parameters and the nonlocal parameters on the wave dispersion characteristics of lipid tubules.

Automated summary

In this paper, wave dispersion analysis of lipid tubules is conducted using FSD shell theory, revealing small-scale effects and considering different types of lipid tubules with size-dependent material properties. Analytical solutions for phase velocity and wave frequency of propagated waves are obtained through Hamilton's principle. Detailed investigations highlight the effects of various factors on the wave dispersion characteristics of lipid tubules.