In this paper two theoretical beam models are proposed for the vibration analysis of fluid-conveying nanotubes using the theory of strain gradient elasticity combined with inertia gradients. For comparison purposes, two stress gradient elasticity beam models were also discussed. Both theories were formulated using either the Euler-Bernoulli or the Timoshenko assumptions. Unlike the stress gradient beam models, in which only one material length scale parameter is introduced, the combined strain/inertia gradient beam models include two material length scale parameters related to the inertia and strain gradients, which enable us to investigate the size effect on the dynamical behavior of nanotubes conveying fluid. Results show that the size effect predicted by stress gradient beam models is not pronounced. However, for combined strain/inertia gradient beam models, the natural frequencies obtained display size-dependent properties. For small aspect ratios, the natural frequencies predicted by the combined strain/inertia gradient beam models are much smaller than the stress gradient results. Moreover, the critical flow velocities predicted by the combined strain/inertia gradient beam models are slightly higher than those predicted by the stress gradient beam models, showing that the stability of nanotubes is enhanced due to the consideration of inertia gradients.
AskesHAifantisEC (2009) Gradient elasticity and flexural wave dispersion in carbon nanotbes. Physical Review B80: 195412–195412.
2.
ChangWJLeeHL (2009) Free vibration of a single-walled carbon nanotube containing a fluid flow using the Timoshenko beam model. Physics Letters A373: 982–985.
3.
DeladiSBerenschotJWTasNRKrijnenGJMde BoerJHde BoerMJ (2005) Fabrication of micromachined fountain pen with in situ characterization possibility of nanoscale surface modification. Journal of Micromechanics and Microengineering15: 528–534.
EringenAC (1983) On differential equations of nonlocal elasticity and solutions of screw dislocation and surface waves. Journal of Applied Physics54: 4703–4710.
6.
HeXQWangCMYanYZhangLXNieGH (2008) Pressure dependence of the instability of multiwalled carbon nanotubes conveying fluids. Archive Applied Mechanics78: 637–648.
7.
KhosravianNRafii-TabarH (2007) Computational modelling of the flow of viscous fluids in carbon nanotubes. Journal of Physics D: Applied Physics40: 7046–7046.
8.
KhosravianNRafii-TabarH (2008) Computational modelling of a non-viscous fluid flow in a multi-walled carbon nanotube modelled as a Timoshenko beam. Nanotechnology19: 275703–275703.
9.
KimKHMoldovanNEspinosaHD (2005) A nano fountain probe with sub-100nm molecular writing resolution. Small1: 632–635.
10.
KrönerE (1967) Elasticity theory of materials with long range cohesive forces. International Journal of Solids and Structures3: 731–742.
11.
KuangYDHeXQChenCYLiGQ (2009) Analysis of nonlinear vibrations of double-walled carbon nanotubes conveying fluid. Computational Materials Science45: 875–880.
12.
KuangYDLiSQChanPKLChenCY (2010) A continuum model of the van der Waals interface for determining the critical diameter of nanopumps and its application to analysis of the vibration and stability of nanopump systems. International Journal of Nonlinear Sciences and Numerical Simulation11: 121–133.
13.
LeeHLChangWJ (2008) Free transverse vibration of the fluid-conveying single-walled carbon nanotube using nonlocal elastic theory. Journal of Applied Physics103: 024302–024302.
14.
LeeHLChangWJ (2009) Vibration analysis of fluid-conveying double-walled carbon nanotubes based on nonlocal elastic theory. Journal of Physics: Condensed Matter21: 115302–115302.
15.
LonghurstMJQuirkeN (2007) Temperature-driven pumping of fluid through single-walled carbon nanotubes. Nano Letters7: 3324–3328.
16.
MindlinRD (1964) Micro-structure in linear elasticity. Archive for Rational Mechanics and Analysis16: 51–78.
17.
NatsukiTNiQQEndoM (2007) Wave propagation in single- and double-walled carbon nanotubes filled with fluids. Journal of Applied Physics101: 034319–034319.
18.
PagonaGTagmatarchisN (2006) Carbon nanotubes: materials for medicinal chemistry and biotechnological applications. Current Medicinal Chemistry13: 1789–1798.
19.
PaidoussisMPLiGX (1993) Pipes conveying fluid: a model dynamical problem. Journal of Fluids and Structures8: 137–204.
TounsiAHeirecheHBediaEAA (2009) Comment on ‘Free transverse vibration of the fluid-conveying single-walled carbon nanotube using nonlocal elastic theory’. [Journal of Applied Physics 103: 024302, (2008)]. Journal of Applied Physics105: 126105–126105.
24.
TravisKPGubbinsKE (2000) Poiseuille flow of Lennard-Jones fluids in narrow slit pores. Journal of Chemical Physics112: 1984–1994.
25.
TravisKPToddBDEvansDJ (1997) Departure from Navier-Stokes hydrodynamics in confined liquids. Physical Review E55: 4288–4288.
26.
WangJ (2005) Carbon-nanotube based electrochemical biosensors: a review. Electroanalysis17: 7–14.
27.
WangL (2009a) Dynamical behaviors of double-walled carbon nanotubes conveying fluid accounting for the role of small length scale. Computational Materials Science45: 584–588.
28.
WangL (2009b) Vibration and instability analysis of tubular nano- and micro-beams conveying fluid using nonlocal elastic theory. Physica E41: 1835–1840.
29.
WangL (2010a) Vibration analysis of fluid-conveying nanotubes with consideration of surface effects. Physica E43: 437–439.
30.
WangL (2010b) Wave propagation of fluid-conveying single-walled carbon nanotubes via gradient elasticity theory. Computational Materials Science49: 761–766.
31.
WangLNiQ (2009) A reappraisal of the computational modelling of carbon nanotubes conveying viscous fluid. Mechanics Research Communications36: 833–837.
WangXYWangXShengGG (2007) The coupling vibration of fluid-filled carbon nanotubes. Journal of Physics D: Applied Physics40: 2563–2572.
36.
XiaWWangL (2010) Vibration characteristics of fluid-conveying carbon nanotubes with curved longitudinal shape. Computational Materials Science49: 99–103.
37.
YanYHeXQZhangLXWangQ (2007) Flow-induced instability of double-walled carbon nanotubes based on an elastic shell model. Journal of Applied Physics102: 044307–044307.
38.
YanYHeXQZhangLXWangCM (2009a) Dynamic behavior of triple-walled carbon nanotubes conveying fluid. Journal of Sound and Vibration319: 1003–1018.
39.
YanYWangWQZhangLX (2009b) Nonlinear vibration characteristics of fluid-filled double-walled carbon nanotubes. Modern Physics Letters B23: 2625–2636.
YoonJRuCQMioduchowskiA (2005) Vibration and instability of carbon nanotubes conveying fluid. Composites Science and Technology65: 1326–1336.
42.
YoonJRuCQMioduchowskiA (2006) Flow-induced flutter instability of cantilever carbon nanotubes. International Journal of Solids and Structures43: 3337–3349.
