For Better Performance Please Use Chrome or Firefox Web Browser

Publications

ISI
sort descending
M.Javanbakht, M.Shakeri, S.N.Sadeghi. Dynamic analysis of functionally graded shell with piezoelectric layers based on elasticity. Proceeding of the Institution of Mechanical Engineers Part C, 223, 2039-2047, 2009. Spring 2009
M. Shakeri, S. N. Sadeghi, M. Javanbakht, H.Hatamikian. Dynamic analysis of functionally graded plate integrated with two piezoelectric layers, based on three dimensional elasticity solution. Proc. of the Institution of Mech. Engineers Part C, 2009. Spring 2009
Valery I. Levitas and Mahdi Javanbakht. Phase-field approach to martensitic phase transformations: effect of martensite-martensite interface energy. International Journal of Materials Research, 102 (6), 2011. Summer 2011
M. Javanbakht, M. Shakeri, S. N. Sadeghi and A. R. Daneshmehr. The analysis of functionally graded shallow and non-shallow shell panels with piezoelectric layers under dynamic load and electrostatic excitation based on elasticity. European Journal of Mech Fall 2011
Valery I. Levitas and Mahdi Javanbakht. Surface tension and energy in multivariant martensitic transformations: phase-field theory, simulations, and model of coherent interface. Physical Review Letters, 105, 165701, 2010. Fall 2011
Valery I. Levitas and Mahdi Javanbakht. Surface-induced phase transformations: multiple scale and mechanics effects and morphological transitions. Physical Review Letters, 107, 175701, 2011. Fall 2011
Valery I. Levitas and Mahdi Javanbakht. Advanced phase-field approach to dislocation evolution. Physical Review B Rapid Communications, 86, 140101, 2012. Fall 2012
M. Javanbakht, A. R. Daneshmehr, M. Shakeri, and A. R. Nateghi. The dynamic analysis of the functionally graded piezoelectric (FGPM) shell panel based on three-dimensional elasticity theory. Applied Mathematical Modeling, 36, 5320–5333, 2012. Spring 2012
Valery I. Levitas and Mahdi Javanbakht. Phase field approach to interaction of phase transformation and dislocation evolution. Applied Physics Letters, 102, 251904, 2013. Summer 2013
Valery I. Levitas and Mahdi Javanbakht. Phase transformations in nanograin materials under high pressure and plastic shear: nanoscale mechanisms. Nanoscale, 6, 162-166, 2014. Fall 2014
Valery I. Levitas and Mahdi Javanbakht. Interaction of phase transformations and plasticity at the nanoscale: phase field approach. Materials Today: Proceedings. 2, Suppl. 3, 2015, S493-S498 Spring 2015
Valery I. Levitas and Mahdi Javanbakht. Interaction between phase transformations and dislocations at the nanoscale. Part 1. General phase field approach. Journal of the Mechanics and Physics of Solids. 82, 2015, 287-319 Spring 2015
Mahdi Javanbakht and Valery I. Levitas. Interaction between phase transformations and dislocations at the nanoscale. Part 2. Phase field simulation examples. Journal of the Mechanics and Physics of Solids. 82, 2015, 164-185 Spring 2015
Valery I. Levitas and Mahdi Javanbakht. Thermodynamically consistent phase field approach to dislocation evolution at small and large strains. Journal of the Mechanics and Physics of Solids. 82, 2015, 345-366 Spring 2015
Mahdi Javanbakht and Ehsan Barati. Martensitic phase transformations in shape memory alloy: phase field modelling with surface tension effect. Computational Materials Science,115, 2016, 137-144. April 2016
Mahdi Javanbakht and Valery I. Levitas, Phase field approach to dislocation evolution at large strains: Computational aspects. International Journal of Solids and Structures. 82, 2016, 95–110. March 2016