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Microsystem Technologies
Erschienen in: Microsystem Technologies 12/2020

18.04.2020 | Technical Paper

Stability analysis of restrained nanotubes placed in electromagnetic field

verfasst von: Büşra Uzun, Uğur Kafkas, Mustafa Özgür Yaylı

Erschienen in: Microsystem Technologies | Ausgabe 12/2020

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Abstract

In this present work, buckling analysis of restrained nanotubes placed in electromagnetic field is studied on the basis of Euler–Bernoulli beam theory in conjunction with Eringen’s nonlocal elasticity theory. The modal displacement function is assumed for the stability analysis in order to discretize the derived governing equation. A Fourier sine series with Stoke’s transformation is utilized to investigate the buckling response. The essential advantage of this transformation is its ability of dealing with various boundary conditions to determine the buckling loads. For demonstrate the effects of various parameters such as Hartmann parameter, spring parameter and mode number on the stability response and critical buckling load of electromagnetic nanobeam a detailed study is presented. Variations of buckling loads, critical buckling loads and buckling load ratios of the nanobeam are exhibited with a number of tables and plotted figures. The results obtained from the analysis are discussed on the tables and figures.
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Literatur
Aifantis EC (1999) Strain gradient interpretation of size effects. Int J Fract 95:299–314
Akgöz B, Civalek Ö (2016) Bending analysis of embedded carbon nanotubes resting on an elastic foundation using strain gradient theory. Acta Astronaut 119:1–12
Arda M (2018) vibration analysis of an axially loaded viscoelastic nanobeam. Int J Eng Appl Sci 10(3):252–263
Arda M, Aydogdu M (2017) Buckling of eccentrically loaded carbon nanotubes. In: Bendikienė R, Juzėnas K (eds) Solid state phenomena, vol 267. Trans Tech Publications Ltd. pp 151–156
Arda M, Aydogdu M (2018) Longitudinal magnetic field effect on torsional vibration of carbon nanotubes. J Comput Appl Mech 49(2):304–313
Arda M, Aydogdu M (2019a) Dynamic stability of harmonically excited nanobeams including axial inertia. J Vib Control 25(4):820–833MathSciNet
Arda M, Aydogdu M (2019b) Torsional dynamics of coaxial nanotubes with different lengths in viscoelastic medium. Microsyst Technol 25(10):3943–3957
Arda M, Aydogdu M (2019c) Dynamic Analysis of a Viscoelastic Nanobeam. In: Karjust K, Kübarsepp J, Otto T, Hussainova I (eds) Key engineering materials, vol 799. Trans Tech Publications, pp 223–229
Avcar M (2014) Free vibration analysis of beams considering dif-ferent geometric characteristics and boundary conditions. System 4(2):2
Chakraverty S, Jena SK (2018) Free vibration of single walled carbon nanotube resting on exponentially varying elastic foundation, curved layer. Structures 5:260–272
Civalek Ö, Akgöz B (2010) Free vibration analysis of micro-tubules as cytoskeleton components: nonlocal Euler-Bernoulli beam modeling. Sci Iranica Trans B Mech Eng 17:367–375MATH
Civalek Ö, Demir Ç (2011) Bending analysis of microtubules using nonlocal Euler–Bernoulli beam theory. Appl Math Model 35:2053–2067MathSciNetMATH
Civalek Ö, Demir C (2016) A simple mathematical model of microtubules surrounded by an elastic matrix by nonlocal finite element method. Appl Math Comput 289:335–352MathSciNetMATH
Demir C, Civalek Ö (2013) Torsional and longitudinal frequency and wave response of microtubules based on the nonlocal continuum and nonlocal discrete models. Appl Math Modell 37(22):9355–9367MATH
Eltaher MA, Emam SA, Mahmoud FF (2013) Static and stability analysis of nonlocal functionally graded nanobeams. Compos Struct 96:82–88
Eringen AC (1967) Theory of micropolar plates. J Appl Math Phys 18:12–30
Eringen AC (1983) On differential equations of nonlocal elas-ticity and solutions of screw dislocation and surface waves. J Appl Phys 54:4703–4710
Giunta G, Crisafulli D, Belouettar S, Carrera E (2011) Hierar-chical theories for the free vibration analysis of functionally graded beams. Compos Struct 94(1):68–74
Gorgani HH, Adeli MM, Hosseini M (2019) Pull-in behavior of functionally graded micro/nano-beams for MEMS and NEMS switches. Microsyst Technol 25(8):3165–3173
Gürses M, Akgöz B, Civalek Ö (2012) Mathematical model-ing of vibration problem of nano-sized annular sector plates using the nonlocal continuum theory via eight-node discrete singular convolution transformation. Appl Math Comput 219:3226–3240MathSciNetMATH
Jena SK, Chakraverty S (2018a) Free vibration analysis of Euler-Bernoulli nanobeam using differential transform method. Int J Comput Mater Sci Eng 7:1850020
Jena SK, Chakraverty S (2018b) Free vibration analysis of variable cross-section single layered graphene nano-ribbons (SLGNRs) using differential quadrature method. Front Built Environ 4:63
Jena SK, Chakraverty S (2018c) Free vibration analysis of single walled carbon nanotube with exponentially varying stiffness, curved layer. Structures 5:201–212
Jena RM, Chakraverty S (2019a) residual power series method for solving time-fractional model of vibration equa-tion of large membranes. J Appl Comput Mech 5:603–615
Jena SK, Chakraverty S (2019b) Differential quadrature and differential transformation methods in buckling analysis of nanobeams, curved layer. Structures 6:68–76
Jena SK, Chakraverty S (2019c) Dynamic behavior of an electromagnetic nanobeam using the Haar wavelet method and the higher-order Haar wavelet method. Eur Phys J Plus 134:538
Jena SK, Chakraverty S, Jena RM, Tornabene F (2019a) A novel fractional nonlocal model and its application in buckling analysis of Euler-Bernoulli nanobeam. Mater Res Express 6:1–17
Jena SK, Chakraverty S, Tornabene F (2019b) Vibration characteristics of nanobeam with exponentially varying flexural rigidity resting online early vary ingelastic foundation using differential quadrature method. Mater Res Express 6:1–13
Jena SK, Chakraverty S, Tornabene F (2019c) Dynamical behavior of nanobeam embedded in constant, linear, parabolic and sinusoidal types of winkler elastic foundation using first-order nonlocal strain gradient model. Mater Res Express 6:0850f2
Jena RM, Chakraverty S, Jena SK (2019d) Dynamic response analysis of fractionally damped beams subjected to external loads using homotopy analysis method. J Appl Comput Mech 5:355–366
Jena SK, Chakraverty S, Tornabene F (2019e) Buckling behavior of nanobeams placed in electromagnetic field using shifted Chebyshev polynomials-based Rayleigh-Ritz method. Nanomaterials 9(1326):1–15
Khalili SMR, Jafari AA, Eftekhari SA (2010) A mixed Ritz-DQ method for forced vibration of functionally graded beams carrying moving loads. Compos Struct 92(10):2497–2511
Koiter WT (1964) Couple stresses in the theory of elasticity: I and II. Proc K Ned Akad Wet B Phys Sci 67:17–44MathSciNetMATH
Lam DCC, Yang F, Chong ACM, Wang J, Tong P (2003) Experiments and theory in strain gradient elasticity. J Mech Phys Solids 51(8):1477–1508MATH
Li SR, Batra RC (2013) Relations between buckling loads of functionally graded Timoshenko and homogeneous Euler-Bernoulli beams. Compos Struct 95:5–9
Lu P, Lee HP, Lu C, Zhang PQ (2006) Dynamic proper-ties of flexural beams using a nonlocal elasticity model. J Appl Phys 99:73510–73518
Mercan K, Civalek Ö (2016a) Buckling analysis of silicon carbide nanotubes (SiCNTs). Int J Eng Appl Sci 8(2):101–108MathSciNet
Mercan K, Civalek Ö (2016b) DSC method for buckling analysis of boron nitride nanotube (BNNT) surrounded by an elastic matrix. Compos Struct 143:300–309
Mercan K, Demir Ç, Akgöz B, Civalek Ö (2015) Coordi-nate transformation for sector and annular sector shaped graphene sheets on silicone matrix. Int J Eng Appl Sci 7(2):56–73
Miandoab EM, Yousefi-Koma A, Pishkenari HN (2015) Nonlocal and strain gradient based model for electrostatically actuated silicon nano-beams. Microsyst Technol 21(2):457–464MATH
Mindlin RD (1963) Influence of couple-stresses on stress concen-trations. Exp Mech 3(1):1–7
Mindlin RD (1965) Second gradient of strain, surface-tension in linear elasticity. Int J Solids Struct 1(4):417–438
Mindlin RD, Tiersten HF (1962) Effects of couple-stresses in linear elasticity. Arch Ration Mech Anal 11:415–448MathSciNetMATH
Murmu T, Pradhan SC (2009) Small-scale effect on the vibration of nonuniform nanocantilever based on nonlocal elasticity theory. Phys E 41:1451–1456
Numanoğlu HM, Akgöz B, Civalek Ö (2018) On dynamic analysis of nanorods. Int J Eng Sci 130:33–50
Rahmani O, Pedram O (2014) Analysis and modeling the size effect on vibration of functionally graded nanobeams based on nonlocal Timoshenko beam theory. Int J Eng Sci 77:55–70MathSciNetMATH
Reddy JN, Pang SD (2008) Nonlocal continuum theories of beam for the analysis of carbon nanotubes. J Appl Phys 103:1–16
Setoodeh AR, Khosrownejad M, Malekzadeh P (2011) Exact nonlocal solution for post buckling of single-walled carbon nanotubes. Phys E 43:1730–1737
Thai HT (2012) A nonlocal beam theory for bending, buckling, and vibration of nanobeams. Int J Eng Sci 52:56–64MathSciNetMATH
Toupin RA (1962) Elastic materials with couple-stresses. Arch Ration Mech Anal 11(1):385–414MathSciNetMATH
Uzun B, Civalek Ö (2019a) Nonlocal FEM formulation for vibration analysis of nanowires on elastic matrix with different materials. Math Comput Appl 24(2):38MathSciNet
Uzun B, Civalek Ö (2019b) Free vibration analysis Silicon nanowires surrounded by elastic matrix by nonlocal finite element method. Adv Nano Res 7(2):99
Uzun B, Yaylı MÖ (2020) Nonlocal vibration analysis of Ti-6Al-4V/ZrO2 functionally graded nanobeam on elastic matrix. Arab J Geosci 13(4):1–10
Uzun B, Numanoglu HM, Civalek Ö (2018) Free vibration analysis of BNNT with different cross-Sections via non-local FEM. J of Comput Appl Mech 49(2):252–260
Uzun B, Yaylı MÖ, Deliktaş B (2020) Free vibration of FG nanobeam using a finite-element method. Micro Nano Lett 15(1):35–40
Wang CM, Kitipornchai S, Lim CW, Eisenberger M (2008) Beam bending solutions based on nonlocal Timoshenko beam theory. J Eng Mech 134:475–481
Yang F, Chong ACM, Lam DCC, Tong P (2002) Couple stress based strain gradient theory for elasticity. Int J Solids Struct 39(10):2731–2743MATH
Yayli MÖ (2015a) Buckling analysis of a rotationally re-strained single walled carbon nanotube. Acta Phys Pol A 127(3):678–683
Yayli MÖ (2015b) Stability analysis of gradient elastic microbeams with arbitrary boundary conditions. J Mech Sci Technol 29(8):3373–3380
Yayli MÖ (2016a) Buckling analysis of a rotationally re-strained single walled carbon nanotube embedded ın an elastic medium using nonlocal elasticity. Int J Eng Appl Sci 8(2):40–50
Yayli MÖ (2016b) An analytical solution for free vibrations of a cantilever nanobeam with a spring mass system. Int J Eng Appl Sci 7(4):10–18
Zakaria M, Al Harthy AM (2017) Free vibration of pre-tensioned electromagnetic nanobeams, IOSR. J Math 13:47–55
Metadaten
Titel
Stability analysis of restrained nanotubes placed in electromagnetic field
verfasst von
Büşra Uzun
Uğur Kafkas
Mustafa Özgür Yaylı
Publikationsdatum
18.04.2020
Verlag
Springer Berlin Heidelberg
Erschienen in
Microsystem Technologies / Ausgabe 12/2020
Print ISSN: 0946-7076
Elektronische ISSN: 1432-1858
DOI
https://doi.org/10.1007/s00542-020-04847-0

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