Abstract
This research explores the dynamic behaviour of horn-shaped single-walled carbon nanotubes (HS-SWCNTs) conveying viscous nanofluid with pulsating the influence of a longitudinal magnetic field. The analysis utilizes Euler–Bernoulli beam model, considering the variable cross section, and incorporating Eringen’s nonlocal theory to formulate the governing partial differential equation of motion. The instability domain of HS-SWCNTs is estimated using Galerkin’s approach. Numerical analysis is performed using the Haar wavelet method. The critical buckling load obtained in this study is compared with previous research to validate the proposed model. The results highlight the effectiveness of the proposed model in assessing the vibrational characteristics of a complex multi-physics system involving HS-SWCNTs. Dispersion graphs and tables are presented to visualize the numerical findings pertaining to various system parameters, including the nonlocal parameter, magnetic flux, Knudsen number, and viscous factor.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Data Availability
The datasets generated and/or analysed during the current study are available from the corresponding author upon reasonable request.
References
Eringen AC. On differential equation of nonlocal elasticity and solution. J Appl Phys. 1983;54:4703–10.
Eringen AC, Edelen DGB. On nonlocal elasticity. Int J Eng Sci. 1972;10:233–48.
Wu XC, Tao YR, Lu YN, et al. High-pressure pyrolysis of melamine route to nitrogen-doped conical hollow and bamboo-like carbon nanotubes. Diam Relat Mater. 2006;15(1):164–70.
Sawant SY, Somani RS, Bajaj HC. A solvothermal-reduction method for the production of horn shaped multi-wall carbon nanotubes. Carbon. 2010;48:668–72.
Wu X, Tao Y, Mao C, et al. Synthesis of nitrogen-doped horn-shaped carbon nanotubes by reduction of pentachloro pyridine with metallic sodium. Carbon. 2007;45:2253–9.
Tang HL, Li DK, Zhou SH. Vibration of horn-shaped carbon nanotube with attached mass via nonlocal elasticity theory. Phys E. 2014;56:306–11.
Ghavanloo E, Fazelzadeh SA. Flow-thermoelastic vibration and instability analysis of viscoelastic carbon nanotubes embedded in viscous fluid. Phys E. 2011;44:17–24.
Zhou J, Chang X, Xiong Z, Li Y. Stability and nonlinear vibration analysis of fluid-conveying composite pipes with elastic boundary conditions. Thin Walled Struct. 2022;179:109597.
Ebrahimi R. Bifurcation analysis of double-walled carbon nanotubes conveying fluid subjected to van der Waals nonlinear forces. J Sound Vib. 2022;11(21):172–86.
Jin Q, Yuan FG, Ren Y. Resonance interaction of flow-conveying nanotubes under forced vibration. Acta Mech. 2023;234(6):2497–517.
Tavakolian F, Farrokhabadi A, Mirzaei M. Pull-in instability of double clamped microbeams under dispersion forces in the presence of thermal and residual stress effects using nonlocal elasticity theory. Microsyst Technol. 2017;23:839–48.
Li L, Hu Y, Ling L. Wave propagation in viscoelastic single-walled carbon nanotubes with surface effect under magnetic field based on nonlocal strain gradient theory. Phys E. 2016;75:118–24.
Karlicic D, Kozic P, Pavlovic R, et al. Dynamic stability of single-walled carbon nanotube embedded in a viscoelastic medium under the influence of the axially harmonic load. Compos Struct. 2017;162:227–43.
Güven U. Transverse vibrations of single-walled carbon nanotubes with initial stress under magnetic field. Compos Struct. 2014;114:92–8.
Zhang DP, Lei Y, Shen ZB. Effect of longitudinal magnetic field on vibration characteristics of single-walled carbon nanotubes in a viscoelastic medium. Braz J Phys. 2017;47:640–56.
Liu H, Liu Y, Dai J, et al. An improved model of carbon nanotube conveying flow by considering comprehensive effects of Knudsen number. Microfluid Nanofluidics. 2018;22:66.
Ariaratnam ST, Namachchivaya NS. Dynamic stability of pipes conveying pulsating fluid. J Sound Vib. 1986;107(2):215–30.
Panda LN, Kar RC. Nonlinear dynamics of a pipe conveying pulsating fluid with parametric and internal resonances. Nonlinear Dyn. 2007;49(1–2):9–30.
Panda LN, Kar RC. Nonlinear dynamics of a pipe conveying pulsating fluid with combination, principal parametric and internal resonances. J Sound Vib. 2008;309(3–5):375–406.
Ni Q, Zhang Z, Wang L, et al. Nonlinear dynamics and synchronization of two coupled pipes conveying pulsating fluid. Acta Mech Solid Sin. 2014;27(2):162–71.
Ni Q, Tang M, Wang Y, et al. In-plane and out-of-plane dynamics of a curved pipe conveying pulsating fluid. Nonlinear Dyn. 2014;75(3):603–19.
Hao MY, Ding H, Mao XY, et al. Stability and nonlinear response analysis of parametric vibration for elastically constrained pipes conveying pulsating fluid. Acta Mech Solida Sin. 2023;36(2):230–40.
Xie WD, Gao XF, Xu WH. Stability and nonlinear vibrations of a flexible pipe parametrically excited by an internal varying flow density. Acta Mech Solid Sin. 2020;36(1):206–19.
Azrar A, Azrar L, Aljinaidi AA. Numerical modelling of dynamic and parametric instabilities of single-walled carbon nanotubes conveying pulsating and viscous fluid. Compos Struct. 2015;125:127–43.
Amiri A, Talebitooti R, Li L. Wave propogation is viscous–fluid–conveying piezoelectric nanotubes considering surface stress effects and Knudsen number based on nonlocal strain gradient theory. Eur Phys J Plus. 2018;133:252.
Lei XW, Natsuki T, Shi JX, et al. Surface effects on the vibrational frequency of double-walled carbon nanotubes using the nonlocal Timoshenko beam model. Compos B Eng. 2012;43:64–9.
Chen CF, Hsiao CH. Haar wavelet method for solving lumped and distributed-parameter systems. IEE Proc Contr Theor Appl. 1997;144(1):87–94.
Hein H, Feklistova L. Computationally efficient delamination detection in composite beams using Haar wavelets. Mech Syst Signal Pr. 2011;25(6):2257–70.
Heydari MH, Hooshmandasl MR, Mohammadi F, et al. Wavelets method for solving systems of nonlinear singular fractional Volterra integro-differential equations. Commun Nonlinear Sci Numer Simul. 2014;19(1):37–48.
Hsiao CH. A Haar wavelets method of solving differential equations characterizing the dynamics of a current collection system for an electric locomotive. Appl Math Comp. 2015;265:928–35.
Jin G, Xie X, Liu Z. The Haar wavelet method for free vibration analysis of functionally graded cylindrical shells based on the shear deformation theory. Compos Struct. 2014;108:435–48.
Jena SK, Chakravarty S, Malikan M. Implementation of Haar wavelet, higher order Haar wavelet, and differential quadrature methods on buckling response of strain gradient nonlocal beam embedded in an elastic medium. Eng Comput. 2021;37:1251–64.
Selvamani R, Mahaveersreejayan M, Dimitri R, et al. Nonlinear magneto-thermo-elastic vibration of mass sensor armchair carbon nanotube resting on an elastic substrate. Curved Layer Struct. 2020;7:153–65.
Selvamani R, Mahaveersreejayan M, Ebrahimi F. Nonlinear ultrasonic waves in a magneto-Flexo-thermally actuated single walled armchair carbon nanotube embedded on polymer matrix. World J Eng. 2020;8(1):1–13.
Mahaveersreejayan M, Kumar R, Selvamani R, et al. Nonlocal dispersion analysis of a fluid-conveying thermo elastic armchair single walled carbon nanotube under moving harmonic excitation. J Solid Mech. 2020;12(1):189–203.
Wu DH, Chien WT, Chen CS, et al. Resonant frequency analysis of fixed-free single-walled carbon nanotube-based mass sensor. Sens Actuators A Phys. 2006;126(1):117–21.
Arda M, Aydogdu M. Vibration analysis of carbon nanotube mass sensors considering both inertia and stiffness of the detected mass. Mech Based Des Struct Mach. 2020;50:1–17.
Liu H, Zheng L. Modeling of novel nanoscale mass sensor made of smart FG magneto-electro-elastic nanofilm integrated with graphene layers. Thin-Walled Struct. 2020;151:106749.
Lee HH, Hsu JC, Chang WJ. Frequency shift of carbon-nanotube-based mass sensor using nonlocal elasticity theory. Nanoscale Res Lett. 2010;5:1774–8.
Aydogdu M, Filiz S. Modeling carbon nanotube-based mass sensors using axial vibration and nonlocal elasticity. Phys E. 2011;43:1229–34.
Funding
The authors declare that no funds, grants, or other support were received during the preparation of this manuscript.
Author information
Authors and Affiliations
Contributions
The study was conceived and designed by Author A, while M. Mahaveer Sree Jayan was responsible for material preparation, data collection, and analysis. Authors B and C reviewed and edited the manuscript, and Author D contributed to data collection and document alignment. All authors have reviewed and approved the final manuscript.
Corresponding author
Ethics declarations
Conflict of interest
The authors have no competing interests to declare that are relevant to the content of this article.
Ethical Approval
This article does not report on or involve the use of any animal or human data or tissue, and the authors gave consent to participate.
Consent for Publication
The authors gave their consent for publication.
Rights and permissions
Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.
About this article
Cite this article
Jayan, M.M.S., Wang, L., Selvamani, R. et al. Analysis of Vibrational Properties of Horn-Shaped Magneto-Elastic Single-Walled Carbon Nanotube Mass Sensor Conveying Pulsating Viscous Fluid Using Haar Wavelet Technique. Acta Mech. Solida Sin. (2024). https://doi.org/10.1007/s10338-023-00457-1
Received:
Revised:
Accepted:
Published:
DOI: https://doi.org/10.1007/s10338-023-00457-1