1. Moshtaghzadeh, M., Bakhtiari, A. and Mardanpour, P., 2022. Artificial Neural Network-based Finite Element method for assessing fatigue and stability of an origami-inspired structure. Engineering Structures, 272, p.114965.
  2. Moshtaghzadeh, M., Bakhtiari, A., Izadpanahi, E. and Mardanpour, P., 2022. Artificial Neural Network for the prediction of fatigue life of a flexible foldable origami antenna with Kresling pattern. Thin-Walled Structures, 174, p.109160
  3. Syed, A.A., Moshtaghzadeh, M., Hodges, D.H. and Mardanpour, P., 2022. Aeroelasticity of Flying-Wing Aircraft Subject to Morphing: A Stability Study. AIAA Journal, 60(9), pp.5372-5385.
  4. Moshtaghzadeh,, Izadpanahi, E. and Mardanpour, P., 2021. Prediction of Fatigue Life of a Flexible Foldable Origami Antenna with Kresling Pattern. Engineering Structures, Volume 251, 2022,113399.
  5. Moshtaghzadeh,, Izadpanahi, E., Bejan, A. and Mardanpour, P., 2021. Evolutionary Aeroelastic Design of Flying Wing Cross Section. AIAA Journal, pp.1-12.
  6. Moshtaghzadeh,, Izadpanahi, E. and Mardanpour, P., 2021. Stability analysis of an origami helical antenna using geometrically exact fully intrinsic nonlinear composite beam theory. Engineering Structures, 234, p.111894.
  7. Mardanpour, P., Izadpanahi,, Powell, S., Rastkar, S. and Bejan, A., 2021. Inflected wings in flight: Uniform flow of stresses makes strong and light wings for stable flight. Journal of Theoretical Biology, 508, p.110452.
  8. Izadpanahi, , Rastkar, S. and Mardanpour, P., 2019. Constructal Design of Flying Wing Aircraft: Curved and Swept Configurations. AIAA Journal, 57(12), pp.5527-5542.
  9. Izadpanahi, E., Rastkar, S., Zisis, I., Fazelzadeh, S.A. and Mardanpour, P., 2019. Nonlinear time domain and stability analysis of beams under partially distributed follower force. Applied Mathematical Modelling73, pp.303-326.
  10. Mardanpour, P., Izadpanahi, , Rastkar, S., Lorente, S. and Bejan, A., 2019. Constructal Design of Aircraft: Flow of Stresses and Aeroelastic Stability. AIAA Journal, 57(10), pp.4393-4405.
  11. Mardanpour, P., Izadpanahi, , Rastkar, S., Calastawad, S. and Levy, C., 2018. Effect of shooting and blast-induced gust on nonlinear aeroelastic stability and behavior of high-aspect ratio wing. Journal of Sound and Vibration433, pp.299-313.
  12. Mardanpour, P., Izadpanahi, E., Rastkar, S., Fazelzadeh, S.A. and Hodges, D.H., 2018. Geometrically exact, fully intrinsic analysis of pre-twisted beams under distributed follower forces. AIAA Journal, 56(2), pp.836-848.
  13. Mardanpour, P. and Rastkar, S., 2017. Constructal Theory and Aeroelastic Design of Flexible Flying Wing Aircraft. Aerospace4(3), p.35.
  14. Mardanpour, P., Izadpanahi, E., Rastkar, S. and Hodges, D.H., 2017. Nonlinear aeroelastic gust suppression and engine placement. Journal of Aircraft54(6), pp.2402-2404.
  15. Fazelzadeh, S.A., Karimi-Nobandegani, A. and Mardanpour, P., 2016. Dynamic stability of pretwisted cantilever beams subjected to distributed follower force. AIAA Journal55(3), pp.955-964.
  16. Richards, P.W., Yao, Y., Herd, R.A., Hodges, D.H. and Mardanpour, P., 2016. Effect of inertial and constitutive properties on body-freedom flutter for flying wings. Journal of Aircraft, 53(3), pp.756-767.
  17. Mardanpour, P. and Hodges, D.H., 2015. On the importance of nonlinear aeroelasticity and energy efficiency in design of flying wing aircraft. Advances in Aerospace Engineering2015.
  18. Mardanpour, P., Hodges, D.H. and Rezvani, R., 2014. Nonlinear aeroelasticity of high-aspect-ratio wings excited by time-dependent thrust. Nonlinear Dynamics75(3), pp.475-500.
  19. Mardanpour, P. and Hodges, D.H., 2014. Passive morphing of flying wing aircraft: Z-shaped configuration. Journal of Fluids and Structures44, pp.17-30.
  20. Mardanpour, P., Hodges, D.H., Neuhart, R. and Graybeal, N., 2013. Engine placement effect on nonlinear trim and stability of flying wing aircraft. Journal of Aircraft50(6), pp.1716-1725.
  21. West, F.D., Shirazi, R., Mardanpour, P., Ozcan, S., Dinc, G., Hodges, D.H., Soleimanpour-Lichaei, H.R. and Nayernia, K., 2013, January. In vitro–derived gametes from stem cells. In Seminars in reproductive medicine(Vol. 31, No. 01, pp. 033-038). Thieme Medical Publishers.