Coupling effects of nonlocal and surface energy on vibration analysis of nanobeams

Faculty Engineering Year: 2013
Type of Publication: ZU Hosted Pages: 760–774
Authors:
Journal: Applied Mathematics and Computation www.elsevier.com Volume:
Keywords : Coupling effects , nonlocal , surface energy , vibration analysis    
Abstract:
This paper is proposed to study the coupled effects of surface properties and nonlocal elasticity on vibration characteristics of nanobeams by using a finite element method. Nonlocal differential elasticity of Eringen is exploited to revea
   
     
 
       

Author Related Publications

  • Mohammed Abdelmoniem Mohamed Eltaher , "Vibrations and stress analysis of rotating perforated beams by using finite elements method", Techno-Press, Ltd., 2021 More
  • Mohammed Abdelmoniem Mohamed Eltaher , "Free vibration of porous FG nonlocal modified couple nanobeams via a modified porosity model", Techno press, 2021 More
  • Mohammed Abdelmoniem Mohamed Eltaher , "Vibration of nonlinear graduation of nano-Timoshenko beam considering the neutral axis position", ScienceDirect, 2014 More
  • Mohammed Abdelmoniem Mohamed Eltaher , "Surface and thermal load effects on the buckling of curved nanowires", Sciencedirect, 2014 More
  • Mohammed Abdelmoniem Mohamed Eltaher , "Modeling of viscoelastic contact-impact problems", journal homepage: www.elsevier.com/locate/apm, 2009 More

Department Related Publications

  • Mohamed Ali Elsayed Mohamed Agwa , "Critical elastic parameters motivating divergence instability of frictional composite infinitely long media", Springer, 2019 More
  • Mohammed Adly AttiaIbrahiem , "On the indentation of elastoplastic functionally graded materials", ScienceDirect, 2019 More
  • Ahmed Wagih Abdallah Abdelhady Deebes, "On the indentation of elastoplastic functionally graded materials", ScienceDirect, 2019 More
  • Alaa Ahmed Abd elrahman , "On the indentation of elastoplastic functionally graded materials", ScienceDirect, 2019 More
  • Tamer Ali Abdella Sebaee, "On the indentation of elastoplastic functionally graded materials", ScienceDirect, 2019 More
Tweet