Dispersion of Transverse Waves in Single-Wall Carbon Nanotubes

M.M. Selima, b aDepartment of Mathematics, College of Science and Humanities in Al-Aflaj, Prince Sattam bin Abdulaziz University, Al-Aflaj 710-11912, Saudi Arabia bDepartment of Mathematics, Suez Faculty of Science, Suez University, Egypt

Received: October 3, 2019; in final form October 10, 2019

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In this work we investigate the influence of initial stress on the transverse waves propagation in single-wall carbon nanotubes with small scale effects under ultrahigh frequency (above k=1nm-1), using the nonlocal continuum theory. The phase and group velocities are derived in a simple way. The effects of wave numbers, scale coefficients and initial stress parameter on phase and group velocity are analyzed. The results show that the dispersion properties of the transverse wave propagation in a single-wall carbon nanotube are induced by small scale effects, which cannot appear in classical models. Also, it is clear that the increase of the scale coefficient and wave number could be strengthened by the dispersion degree of the phase and group velocity of transverse waves. In particular, the analysis shows that the compression initial stress in a single-wall carbon nanotube does not only affect the number of transverse wave speeds and the magnitude of transverse wave speeds, but also the critical value of the wave number at the wave speed changes. The effects of the initial stress and small scale on the transverse wave propagation in single-wall carbon nanotubes may result in some complex dynamic phenomena of terahertz sound waves propagation in the carbon nanotubes, which can be used as a useful reference for the designs of nanodrive devices, nanooscillators and nanosensors.

DOI:10.12693/APhysPolA.136.1018 topics: single-wall carbon nanotubes, transverse waves, Erigena's nonlocal elasticity theory, initial stresses, small scale effect