TY  - CONF
AU  - Karličić, Danilo
AU  - Cajić, Milan
AU  - Kozić, Predrag
AU  - Lazarević, Mihailo
PY  - 2016
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/6567
AB  - In recent years, nonlinear and damping effects have become more important in the study of the dynamic behavior of micro- and nano- systems and devices. Therefore, investigators direct special attention to the  mathematical modeling of the dynamic behavior of nano-structures such as carbon nanotubes, ZnO nanotubes and functionally graded beams.
The functionally graded materials (FGM) are types of structures that are composed of at last two-phase inhomogeneous particulate composite and synthesized in such manner that the volume fractions of constituents vary continuously along any desired spatial direction. This results in smooth variation of mechanical properties along desired direction. Nazemnezhad et al. [1] have analyzed the free nonlinear vibration of FG nanobeam based on the von Karman deformation, Euler-Bernoulli beam theory and nonlocal elasticity. They obtained approximated analytical solution for the nonlinear natural frequency by applying the multiple scales perturbation
method. Ansari et al. [2] proposed nonlinear dynamic model to analyze the nonlinear forced vibration of FG nanobeam in thermal environment based on the surface elasticity theory.
Some authors describe dissipation effects in viscoelastic structures and nanostructures using fractional derivative models [3]. Ansari et al. [4] investigated the nonlinear vibration of a nonlocal fractional viscoelastic nanobeam using numerical methods.
By browsing the literature, the authors found a small number of studies focused on the vibration analysis of FG nanobeams embedded in certain type of medium. In this report, we investigated the dynamical model of a functionally graded (FG) beam modeled as a nanobeam with geometric nonlinearity embedded in a fractional Kelvin-Voigt viscoelastic medium by using the nonlocal continuum theory. The material properties of FG nanobeam vary continuously through thickness direction, which is based on the power-low distribution. We assume that the FG nanobeam has simply-supported boundary conditions and vibrates under the influence of the transversal periodic load. Based on the nonlocal Euler-Bernoulli beam theory, von Karman nonlinear  strain-displacements relation, we obtain the nonlinear fractional partial differential equations of transversal motion of the embedded FG nanobeam. By using the assumption of small fractional damping we employed the perturbation method of multiple-scales to obtain the approximated analytical solution of the governing equation of motion. The relationships between frequency-amplitude and force-amplitude in the presence of fractional damping are derived by using the multiple scales method. It is shown that the nonlocal parameter, fractional damping and material property gradient index have significant effects on the vibration behavior of FG nanobeam
and therefore receive substantial attention.
PB  - Faculty of Mechanical Engineering, Belgrade
PB  - University of Belgrade Mathematical Institute, Serbian Academy of Sciences and Arts
C3  - Booklet of Abstracts Mini-symposium “ Fractional Calculus with applications in problems of diffusion, control and dynamics of complex systems”,  July 13, 2016
T1  - Nonlinear forced vibration of a functionally graded nonlocal nanobeam embedded in a fractional viscoelastic medium
EP  - 26
SP  - 26
UR  - https://hdl.handle.net/21.15107/rcub_machinery_6567
ER  - 

@conference{
author = "Karličić, Danilo and Cajić, Milan and Kozić, Predrag and Lazarević, Mihailo",
year = "2016",
abstract = "In recent years, nonlinear and damping effects have become more important in the study of the dynamic behavior of micro- and nano- systems and devices. Therefore, investigators direct special attention to the  mathematical modeling of the dynamic behavior of nano-structures such as carbon nanotubes, ZnO nanotubes and functionally graded beams.
The functionally graded materials (FGM) are types of structures that are composed of at last two-phase inhomogeneous particulate composite and synthesized in such manner that the volume fractions of constituents vary continuously along any desired spatial direction. This results in smooth variation of mechanical properties along desired direction. Nazemnezhad et al. [1] have analyzed the free nonlinear vibration of FG nanobeam based on the von Karman deformation, Euler-Bernoulli beam theory and nonlocal elasticity. They obtained approximated analytical solution for the nonlinear natural frequency by applying the multiple scales perturbation
method. Ansari et al. [2] proposed nonlinear dynamic model to analyze the nonlinear forced vibration of FG nanobeam in thermal environment based on the surface elasticity theory.
Some authors describe dissipation effects in viscoelastic structures and nanostructures using fractional derivative models [3]. Ansari et al. [4] investigated the nonlinear vibration of a nonlocal fractional viscoelastic nanobeam using numerical methods.
By browsing the literature, the authors found a small number of studies focused on the vibration analysis of FG nanobeams embedded in certain type of medium. In this report, we investigated the dynamical model of a functionally graded (FG) beam modeled as a nanobeam with geometric nonlinearity embedded in a fractional Kelvin-Voigt viscoelastic medium by using the nonlocal continuum theory. The material properties of FG nanobeam vary continuously through thickness direction, which is based on the power-low distribution. We assume that the FG nanobeam has simply-supported boundary conditions and vibrates under the influence of the transversal periodic load. Based on the nonlocal Euler-Bernoulli beam theory, von Karman nonlinear  strain-displacements relation, we obtain the nonlinear fractional partial differential equations of transversal motion of the embedded FG nanobeam. By using the assumption of small fractional damping we employed the perturbation method of multiple-scales to obtain the approximated analytical solution of the governing equation of motion. The relationships between frequency-amplitude and force-amplitude in the presence of fractional damping are derived by using the multiple scales method. It is shown that the nonlocal parameter, fractional damping and material property gradient index have significant effects on the vibration behavior of FG nanobeam
and therefore receive substantial attention.",
publisher = "Faculty of Mechanical Engineering, Belgrade, University of Belgrade Mathematical Institute, Serbian Academy of Sciences and Arts",
journal = "Booklet of Abstracts Mini-symposium “ Fractional Calculus with applications in problems of diffusion, control and dynamics of complex systems”,  July 13, 2016",
title = "Nonlinear forced vibration of a functionally graded nonlocal nanobeam embedded in a fractional viscoelastic medium",
pages = "26-26",
url = "https://hdl.handle.net/21.15107/rcub_machinery_6567"
}

Karličić, D., Cajić, M., Kozić, P.,& Lazarević, M.. (2016). Nonlinear forced vibration of a functionally graded nonlocal nanobeam embedded in a fractional viscoelastic medium. in Booklet of Abstracts Mini-symposium “ Fractional Calculus with applications in problems of diffusion, control and dynamics of complex systems”,  July 13, 2016
Faculty of Mechanical Engineering, Belgrade., 26-26.
https://hdl.handle.net/21.15107/rcub_machinery_6567

Karličić D, Cajić M, Kozić P, Lazarević M. Nonlinear forced vibration of a functionally graded nonlocal nanobeam embedded in a fractional viscoelastic medium. in Booklet of Abstracts Mini-symposium “ Fractional Calculus with applications in problems of diffusion, control and dynamics of complex systems”,  July 13, 2016. 2016;:26-26.
https://hdl.handle.net/21.15107/rcub_machinery_6567 .

Karličić, Danilo, Cajić, Milan, Kozić, Predrag, Lazarević, Mihailo, "Nonlinear forced vibration of a functionally graded nonlocal nanobeam embedded in a fractional viscoelastic medium" in Booklet of Abstracts Mini-symposium “ Fractional Calculus with applications in problems of diffusion, control and dynamics of complex systems”,  July 13, 2016 (2016):26-26,
https://hdl.handle.net/21.15107/rcub_machinery_6567 .

TY  - JOUR
AU  - Karličić, Danilo
AU  - Kozić, Predrag
AU  - Adhikari, Sondipon
AU  - Cajić, Milan
AU  - Murmu, Tony
AU  - Lazarević, Mihailo
PY  - 2015
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/2254
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/3936
AB  - Nano-materials such as graphene sheets have a great opportunity to be applied in development of a new generation of nanomechanical sensors and devices due to their unique physical properties. Based on the nonlocal continuum theory and vibration analysis, the single-layered graphene sheet with attached nanoparticles affected by in-plane magnetic field is proposed as a new type of the mass-nanosensor. The nonlocal Kirchhoff-Love plate theory is adopted to describe mechanical behavior of single-layered graphene sheet as an orthotropic nanoplate. The equation of motion of a simply supported orthotropic nanoplate is derived, where the influence of Lorentz magnetic force is introduced through classical Maxwell's equations. Complex natural frequencies, damped frequency shifts and relative shift of damping ratio for nanoplate with attached nanoparticles are obtained in the explicit form. The influences of the nonlocal and magnetic field parameter, different mass weights and positions of attached nanoparticles and damping coefficients on the relative damped frequency shift and relative shift of damping ratio are examined. The presented results can be useful in the analysis and design of nanosensors applied in the presence of strong magnetic field. Our results show that magnetic field could be successfully used to improve sensibility performances of nanomechanical sensors.
PB  - Pergamon-Elsevier Science Ltd, Oxford
T2  - International Journal of Mechanical Sciences
T1  - Nonlocal mass-nanosensor model based on the damped vibration of single-layer graphene sheet influenced by in-plane magnetic field
EP  - 142
SP  - 132
VL  - 96-97
DO  - 10.1016/j.ijmecsci.2015.03.014
ER  - 

@article{
author = "Karličić, Danilo and Kozić, Predrag and Adhikari, Sondipon and Cajić, Milan and Murmu, Tony and Lazarević, Mihailo",
year = "2015",
abstract = "Nano-materials such as graphene sheets have a great opportunity to be applied in development of a new generation of nanomechanical sensors and devices due to their unique physical properties. Based on the nonlocal continuum theory and vibration analysis, the single-layered graphene sheet with attached nanoparticles affected by in-plane magnetic field is proposed as a new type of the mass-nanosensor. The nonlocal Kirchhoff-Love plate theory is adopted to describe mechanical behavior of single-layered graphene sheet as an orthotropic nanoplate. The equation of motion of a simply supported orthotropic nanoplate is derived, where the influence of Lorentz magnetic force is introduced through classical Maxwell's equations. Complex natural frequencies, damped frequency shifts and relative shift of damping ratio for nanoplate with attached nanoparticles are obtained in the explicit form. The influences of the nonlocal and magnetic field parameter, different mass weights and positions of attached nanoparticles and damping coefficients on the relative damped frequency shift and relative shift of damping ratio are examined. The presented results can be useful in the analysis and design of nanosensors applied in the presence of strong magnetic field. Our results show that magnetic field could be successfully used to improve sensibility performances of nanomechanical sensors.",
publisher = "Pergamon-Elsevier Science Ltd, Oxford",
journal = "International Journal of Mechanical Sciences",
title = "Nonlocal mass-nanosensor model based on the damped vibration of single-layer graphene sheet influenced by in-plane magnetic field",
pages = "142-132",
volume = "96-97",
doi = "10.1016/j.ijmecsci.2015.03.014"
}

Karličić, D., Kozić, P., Adhikari, S., Cajić, M., Murmu, T.,& Lazarević, M.. (2015). Nonlocal mass-nanosensor model based on the damped vibration of single-layer graphene sheet influenced by in-plane magnetic field. in International Journal of Mechanical Sciences
Pergamon-Elsevier Science Ltd, Oxford., 96-97, 132-142.
https://doi.org/10.1016/j.ijmecsci.2015.03.014

Karličić D, Kozić P, Adhikari S, Cajić M, Murmu T, Lazarević M. Nonlocal mass-nanosensor model based on the damped vibration of single-layer graphene sheet influenced by in-plane magnetic field. in International Journal of Mechanical Sciences. 2015;96-97:132-142.
doi:10.1016/j.ijmecsci.2015.03.014 .

Karličić, Danilo, Kozić, Predrag, Adhikari, Sondipon, Cajić, Milan, Murmu, Tony, Lazarević, Mihailo, "Nonlocal mass-nanosensor model based on the damped vibration of single-layer graphene sheet influenced by in-plane magnetic field" in International Journal of Mechanical Sciences, 96-97 (2015):132-142,
https://doi.org/10.1016/j.ijmecsci.2015.03.014 . .

TY  - JOUR
AU  - Karličić, Danilo
AU  - Kozić, Predrag
AU  - Adhikari, Sondipon
AU  - Cajić, Milan
AU  - Murmu, Tony
AU  - Lazarević, Mihailo
PY  - 2015
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/2254
AB  - Nano-materials such as graphene sheets have a great opportunity to be applied in development of a new generation of nanomechanical sensors and devices due to their unique physical properties. Based on the nonlocal continuum theory and vibration analysis, the single-layered graphene sheet with attached nanoparticles affected by in-plane magnetic field is proposed as a new type of the mass-nanosensor. The nonlocal Kirchhoff-Love plate theory is adopted to describe mechanical behavior of single-layered graphene sheet as an orthotropic nanoplate. The equation of motion of a simply supported orthotropic nanoplate is derived, where the influence of Lorentz magnetic force is introduced through classical Maxwell's equations. Complex natural frequencies, damped frequency shifts and relative shift of damping ratio for nanoplate with attached nanoparticles are obtained in the explicit form. The influences of the nonlocal and magnetic field parameter, different mass weights and positions of attached nanoparticles and damping coefficients on the relative damped frequency shift and relative shift of damping ratio are examined. The presented results can be useful in the analysis and design of nanosensors applied in the presence of strong magnetic field. Our results show that magnetic field could be successfully used to improve sensibility performances of nanomechanical sensors.
PB  - Pergamon-Elsevier Science Ltd, Oxford
T2  - International Journal of Mechanical Sciences
T1  - Nonlocal mass-nanosensor model based on the damped vibration of single-layer graphene sheet influenced by in-plane magnetic field
EP  - 142
SP  - 132
VL  - 96-97
DO  - 10.1016/j.ijmecsci.2015.03.014
ER  - 

@article{
author = "Karličić, Danilo and Kozić, Predrag and Adhikari, Sondipon and Cajić, Milan and Murmu, Tony and Lazarević, Mihailo",
year = "2015",
abstract = "Nano-materials such as graphene sheets have a great opportunity to be applied in development of a new generation of nanomechanical sensors and devices due to their unique physical properties. Based on the nonlocal continuum theory and vibration analysis, the single-layered graphene sheet with attached nanoparticles affected by in-plane magnetic field is proposed as a new type of the mass-nanosensor. The nonlocal Kirchhoff-Love plate theory is adopted to describe mechanical behavior of single-layered graphene sheet as an orthotropic nanoplate. The equation of motion of a simply supported orthotropic nanoplate is derived, where the influence of Lorentz magnetic force is introduced through classical Maxwell's equations. Complex natural frequencies, damped frequency shifts and relative shift of damping ratio for nanoplate with attached nanoparticles are obtained in the explicit form. The influences of the nonlocal and magnetic field parameter, different mass weights and positions of attached nanoparticles and damping coefficients on the relative damped frequency shift and relative shift of damping ratio are examined. The presented results can be useful in the analysis and design of nanosensors applied in the presence of strong magnetic field. Our results show that magnetic field could be successfully used to improve sensibility performances of nanomechanical sensors.",
publisher = "Pergamon-Elsevier Science Ltd, Oxford",
journal = "International Journal of Mechanical Sciences",
title = "Nonlocal mass-nanosensor model based on the damped vibration of single-layer graphene sheet influenced by in-plane magnetic field",
pages = "142-132",
volume = "96-97",
doi = "10.1016/j.ijmecsci.2015.03.014"
}

Karličić, D., Kozić, P., Adhikari, S., Cajić, M., Murmu, T.,& Lazarević, M.. (2015). Nonlocal mass-nanosensor model based on the damped vibration of single-layer graphene sheet influenced by in-plane magnetic field. in International Journal of Mechanical Sciences
Pergamon-Elsevier Science Ltd, Oxford., 96-97, 132-142.
https://doi.org/10.1016/j.ijmecsci.2015.03.014

Karličić D, Kozić P, Adhikari S, Cajić M, Murmu T, Lazarević M. Nonlocal mass-nanosensor model based on the damped vibration of single-layer graphene sheet influenced by in-plane magnetic field. in International Journal of Mechanical Sciences. 2015;96-97:132-142.
doi:10.1016/j.ijmecsci.2015.03.014 .

Karličić, Danilo, Kozić, Predrag, Adhikari, Sondipon, Cajić, Milan, Murmu, Tony, Lazarević, Mihailo, "Nonlocal mass-nanosensor model based on the damped vibration of single-layer graphene sheet influenced by in-plane magnetic field" in International Journal of Mechanical Sciences, 96-97 (2015):132-142,
https://doi.org/10.1016/j.ijmecsci.2015.03.014 . .