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Mohammad Rasoul Delfani

 

Associate Professor

Faculty of Civil Engineering, K. N. Toosi University of Technology

Publication

  • Delfani, M. R., & Kosari, H. R. (2022). Interaction of a semi-infinite crack with a screw dislocation within Mindlin's first strain-gradient elasticity. Engineering Fracture Mechanics, 275, 108846.
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  • Delfani, M. R., & Amadeh-Rajiri, S. (2022). Elastic and plastic fields induced by a screw dislocation in a nanowire within Mindlin's second strain gradient theory. Applied Mathematical Modelling, 109, 7797.
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  • Delfani, M. R., Tarvirdilu-Asl, A., & Sajedipour, M. (2022). Elastic fields due to a suddenly expanding spherical inclusion within Mindlin's first strain-gradient theory. Continuum Mechanics and Thermodynamics, 34(3), 697719.
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  • Delfani, M. R. (2021). Closed-form solutions for the elastic fields due to the motion of a screw dislocation at a constant velocity along a linear path with an arbitrary direction. Sharif: Civil engineering, 36(4), 7380.
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  • Delfani, M. R., Taaghi, S., & Tavakol, E. (2020). Uniform motion of an edge dislocation within Mindlin's first strain gradient elasticity. International Journal of Mechanical Sciences, 179, 105701.
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  • Delfani, M. R., & Shodja, H. M. (2020). Dual ideal shear strengths for chiral single-walled carbon nanotubes. International Journal of Non-Linear Mechanics, 120, 103382.
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  • Delfani, M. R., & Kakavand, F. (2019). Frank network of dislocations within Mindlin's second strain gradient theory of elasticity. International Journal of Mechanical Sciences, 164, 105150.
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  • Delfani, M. R., & Forghani-Arani, P. (2019). Interaction of a straight screw dislocation with a circular cylindrical inhomogeneity in the context of second strain gradient theory of elasticity. Mechanics of Materials, 139, 103208.
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  • Delfani, M. R., & Tavakol, E. (2019). Uniformly moving screw dislocation in strain gradient elasticity. European Journal of Mechanics-A/Solids, 73, 349–355.
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  • Delfani, M. R., Shojaeimanesh, S., & Bagherpour, V., (2019). Effective shear modulus of functionally graded fibrous composites in second strain gradient elasticity. Journal of Elasticity, 137(1), 4362.
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  • Delfani, M. R., & Sajedipour, M. (2018). Spherical inclusion with time-harmonic eigenfields in strain gradient elasticity considering the effect of micro inertia. International Journal of Solids and Structures, 155, 57–64.
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  • Delfani, M. R. (2018). Nonlinear elasticity of monolayer hexagonal crystals: Theory and application to circular bulge test. European Journal of Mechanics-A/Solids, 68, 117132.
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  • Delfani, M. R., & Latifi-Shahandashti, M. (2017). Elastic field of a spherical inclusion with non-uniform eigenfields in second strain gradient elasticity. Proceedings of the Royal Society A, 473(2205), 20170254.
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  • Delfani, M. R., & Bagherpour, V. (2017). Overall properties of particulate composites with periodic microstructure in second strain gradient theory of elasticity. Mechanics of Materials, 113, 89101.
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  • Delfani, M. R. (2017). Extended theory of elastica for free torsional, longitudinal, and radial breathing vibrations of single-walled carbon nanotubes. Journal of Sound and Vibration, 403, 104128.
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  • Delfani, M. R. (2017). Two-dimensional elastica model for describing the flexural behavior of single-walled carbon nanotubes. Journal of Elasticity, 126(2), 173199.
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  • Delfani, M. R., & Shodja, H. M. (2016). A large-deformation thin plate theory with application to one-atom-thick layers. Journal of the Mechanics and Physics of Solids, 87, 65–85.
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  • Shodja, H. M., Goodarzi, A., Delfani, M. R., & Haftbaradaran, H. (2015). Scattering of an anti-plane shear wave by an embedded cylindrical nano-fiber within couple stress theory with micro inertia. International Journal of Solids and Structures, 58, 73–90.
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  • Delfani, M. R., & Shodja, H. M. (2015). An exact analysis for the hoop elasticity and pressure-induced twist of CNT-nanovessels and CNT-nanopipes. Mechanics of Materials, 82, 47–62.
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  • Delfani, M. R., & Shodja, H. M. (2013). An enhanced continuum modeling of the ideal strength and the angle of twist in tensile behavior of single-walled carbon nanotubes. Journal of Applied Physics, 114(5), 05352.
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  • Delfani, M. R., Shodja, H. M., & Ojaghnezhad, F. (2013). Mechanics and morphology of single-walled carbon nanotubes: from graphene to the elastica. Philosophical Magazine, 93(17), 2057–2088.
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  • Shodja, H. M., & Delfani, M. R. (2011). A novel nonlinear constitutive relation for graphene and its consequence for developing closed-form expressions for Young’s modulus and critical buckling strain of single-walled carbon nanotubes. Acta Mechanica, 222(12), 91101.
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  • Shodja, H. M., & Delfani, M. R. (2009). 3D elastodynamic fields of non-uniformly coated obstacles: Notion of eigenstress and eigenbody-force fields. Mechanics of Materials, 41(9), 989999.
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  • Sarvestani, A. S., Shodja, H. M., & Delfani, M. R. (2008). Determination of the scattered fields of an SH-wave by an eccentric coating-fiber ensemble using DEIM. International Journal of Engineering Science, 46(11), 11361146.