Nonlocal vibration of carbon/boron-nitride nano-hetero-structure in thermal and magnetic fields by means of nonlinear finite element method

Sedighi, Hamid M.; Malikan, Mohammad; Valipour, Ali; Żur, Krzysztof Kamil

doi:10.1093/jcde/qwaa041

Cited by 21 publications

(11 citation statements)

References 61 publications

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“…As a result, at smaller deflection values, there may be no need to adopt the higher-order non-local strain gradient theories [60]. Sedighi et al [61] simultaneously considered the impacts of length ratio, size dependence, magnetic field, and temperature environment on the nonlinear vibrational properties of composite CNT/BNNT. Figure 4 depicts a doubly clamped nano-heterostructure composed of two different types of tubular materials.…”

Section: Thermal Vibration Of Nanotubementioning

confidence: 99%

“…As a result, the effect of the magneto-thermal environment is also considered while investigating the vibration characteristics of such composite structures. Sedighi et al [61] demonstrated that when the contribution of the boron-nitride section is dominant, the location of the greatest amplitude would shift to the left when considering larger temperature gradients. In addition, they found that the configurations of the non-linear mode forms are substantially influenced by the high-temperature environment.…”

Section: Thermal Vibration Of Nanotubementioning

confidence: 99%

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A review on recent research studies on vibration analysis of fluid-conveying nanotubes

Fatahian¹,

Hosseini

Fatahian³

2020

IJETS

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Nanotube (such as carbon and boron nitride nanotubes) is a key component of modern technology applications of nanostructures due to their unique mechanical, electrical, and physical characteristics such as high elasticity modulus, suitable heat transfer, and electrical conductivity. Carbon and boron nitride nanotubes are among the promising choices in nano-fluidic, gas storage, and drug delivery systems due to their hollow cylindrical shape and appropriate chemical, mechanical, and physical properties. Thermal vibration assessment should be conducted on fluid-conveying carbon nanotubes since the effect of thermal fluctuations on the mechanical characteristics of nanostructure are significant. Previous studies have revealed that when thermal vibration is taken into account, quantum effects can become extremely important in nanoscale electronics and structures. Hence, the present review focuses mostly on previous work on fluid-conveying nanotubes and the dynamical characteristics of size-dependent vibration and non-local strain gradient theory of fluid-conveying nanotubes. Furthermore, a special effort is made to address recent and rare investigations on the vibration of fluid-conveying nanotubes in thermal environment, as well as thermal vibration concerns of carbon nanotubes.

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Section: Thermal Vibration Of Nanotubementioning

confidence: 99%

Section: Thermal Vibration Of Nanotubementioning

confidence: 99%

A review on recent research studies on vibration analysis of fluid-conveying nanotubes

Fatahian¹,

Hosseini

Fatahian³

2020

IJETS

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“…The studies on the static and dynamic analyses with nonlocal elasticity of beams [31][32][33][34][35][36][37][38][39][40][41][42][43][44] and rods [45][46][47][48][49][50][51] have led to an understanding of the mechanical behaviors of atomic-scaled structures. Moreover, the thermal vibration 52 and buckling 53 of Euler-Bernoulli beams, thermal vibrations of Timoshenko beams, 54,55 and vibration of Rayleigh beam axially loading and lying on two-parameter elastic foundation 56 are studied.…”

Section: Introductionmentioning

confidence: 99%

A new eigenvalue problem solver for thermo‐mechanical vibration of Timoshenko nanobeams by an innovative nonlocal finite element method

Numanoğlu

Ersoy

Akgöz

et al. 2021

Math Methods in App Sciences

118

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In this study, size‐dependent thermo‐mechanical vibration analysis of nanobeams is examined. Size‐dependent dynamic equations are obtained by implementing Hamilton's principle based on Timoshenko beam theory and then combined with stress equation of nonlocal elasticity theory. The separation of variables total method and finite element formulation is utilized to solve the eigenvalue problem. Local and nonlocal stiffness and mass matrices are firstly derived by using a weighted residual method for the finite element analysis. The accuracy of the finite element solution is demonstrated by comparisons with the earlier studies. Then, nondimensional frequencies of nanobeams with different boundary conditions based on a nonlocal finite element method are presented for vibration analysis that cannot be analytically solved under different parameters. It is aimed to emphasize the importance of the nonlocal finite element method in the size‐dependent vibration behavior of nanobeams which form different components of nano‐electro‐mechanical systems.

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“…Small-scale devices [1][2][3][4], biological and bioinspired materials [5][6][7], advanced porous nanostructures [8,9], self-healing matter [10], hierarchical and periodic structures [11,12], new-generation of complex composites [13][14][15] require sophisticated methodologies and advanced models to predict their mechanical behavior. Usually, classical models of local continuum elasticity are not accurate enough to simulate the mechanical behavior of these nonconventional structural elements.…”

Section: Introductionmentioning

confidence: 99%

On the nonlocal bending problem with fractional hereditariness

et al. 2021

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Nonlocal hereditariness in Bernoulli–Euler beam is investigated in this paper. An approach to solve that problem is proposed and some analytical solutions are provided. To this aim, time-dependent hereditary behavior is modeled by means of non-integer order operators of the fractional linear viscoelasticity. While, space-dependent nonlocal phenomena are simulated through the integral stress-driven formulation. These two approaches are combined providing a new model able to simulate nonlocal viscoelastic bending problem. Several application samples of the proposed formulation and a thorough parametric study are presented showing the influences of hereditariness and nonlocal effects on the mechanical bending response. Proposed formulation can be useful for design and optimization of structures used in advanced applications when local elastic theory cannot be adopted.

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Nonlocal vibration of carbon/boron-nitride nano-hetero-structure in thermal and magnetic fields by means of nonlinear finite element method

Cited by 21 publications

References 61 publications

A review on recent research studies on vibration analysis of fluid-conveying nanotubes

A review on recent research studies on vibration analysis of fluid-conveying nanotubes

A new eigenvalue problem solver for thermo‐mechanical vibration of Timoshenko nanobeams by an innovative nonlocal finite element method

On the nonlocal bending problem with fractional hereditariness

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